KR20110068236A - Method for unification and design of oceanic structure, and media that can record computer program sources for method thereof - Google Patents

Abstract

PURPOSE: A method for design and integration of oceanic structure is provided to increase work efficiency and reduce working hours by generating a platform structure automatically. CONSTITUTION: An ocean structure design and integration program(100) is installed and operated in a PC. Basic data for construction settings and block-related data computation is set through the program. The material used in construction is selected and default material for the construction is set. A basic joint type for using in a project is added and the dimension of joint by types and welding information is set. A construction file that has set is saved as an Excel format and managed.

Description

Method For Unification And Design Of Oceanic Structure, And Media That Can Record Computer Program Sources for Method Thereof}

The present invention relates to a method for designing and integrating an offshore structure and a recording medium storing a computer program for the method. More specifically, the present invention relates to 3D CAD modeling, drawing generation, and overall requirements. It relates to a method of designing and integrating offshore structures, and to a recording medium storing a computer program for the method, which enables a report to be solved in one CAD.

As the importance of marine development and clean energy increases, the concept of shipbuilding industry, which was divided into shipbuilding and offshore parts, is expanding from the ship builder to the ocean developer. Accordingly, innovation in business areas and design methods is required throughout the shipbuilding industry. In other words, it is necessary to lay the foundation of competitive offshore structure design in the existing offshore industry. For this purpose, in the offshore structure design and integrated system, time delay and simple repetitive work according to individual data input, and long-term relocation of 3D shapes are required. Unnecessary factors, such as requirements and delays in production of various factors, should be minimized.

According to the Ministry of Commerce, Industry and Energy, the major systems of shipbuilding and offshore industry are divided into three categories: design system, production management system, and production automation system.

First, the design system includes basic planning, detailed design and production technology including performance analysis and evaluation as a means to define the performance and function of ships and offshore structures, and to efficiently generate and manage information and data for production and operation. do.

The second production management system includes the design system based on the product model and the process planning and management technology for the optimization of the production system, and aims to complete the simulation-based process planning and network-based collaboration system. Key technologies in this area include Computer Aided Processing Planning (CAPP), Enterprise Resource Planning (ERP), Supply Chain Management (SCM), Knowledge Management System (KMS), and Simulation Based Manufacturing (SBM).

Finally, the production automation system includes facilities for shipbuilding and related software, and aims for an automation system linked with the design and production management system.

Therefore, most shipbuilders have sub-systems based on the above three criteria.

In Korea, large-scale shipyards and heavy industries in Korea, which were newly constructed as the shipbuilding / marine industry grew rapidly in the late 1970s, introduced advanced information systems of the time, including CAD / CAM and MIS. Therefore, the information technology has been widely used since early compared to other industries.

Since the late 1980s, the booming shipbuilding / marine industry has been actively investing in computer hardware and software, mainly CAD / CAM systems, as a means of improving technology and productivity. As a result, in terms of computer hardware, it is forming the basis of shipbuilding / ocean information by constructing a large scale mainframe system such as IBM, a modern engineering workstation, a personal computer, and establishing a Lacal Area Network (LAN) using optical cables.

On the software side, most of the commercial software in foreign countries is introduced and utilized, except for some management systems centered on MIS. However, since it is mainly provided in the form of a black box, there is a limitation in dedicating general-purpose software to the environment of the shipbuilding system. Thus, stable base technology for shipbuilding / ocean support system is insufficient.

With the recent rapid development of computer technology and efforts to build the next generation shipbuilding / oceanic support system based on them, the shipbuilding and marine industry in Japan has moved away from dependence on foreign technology in the 21st century. In preparation for the leap to the world's No. 1 country

Results of the first phase of the development of the Computerized Ship Design and Production System (CSDP), which has been jointly promoted by industry, academia and research since 1988 with the support of the government. In addition to database technology, shipbuilding / marine software development including geometric modeling and visualization technology, graphic user interface (GUI) technology, knowledge base construction and processing technology, and object-oriented modeling technology Secured the basic technology for

However, except for the management system, the shipbuilding field, in particular, the application programs that make up the design and production system partially utilizes a general-purpose or dedicated system in the form of a black box mainly introduced from abroad. As the dependence on these systems grows, the technological basis of the domestic shipbuilding industry is inevitably weakened. Therefore, efforts to develop unique application systems by introducing related technologies including source code have been made by each shipbuilder or jointly. Is being tried.

Currently, some application programs in the initial design and basic design fields are developed in-house and are in practical use, but there is still a limitation in developing a ship's own CAD / CAM system in the domestic environment that lacks core infrastructure technologies such as modeling technology and manpower. .

In addition, the shipbuilding CAD system, which has been introduced since the 1980s, has been developed and improved for 30 years with the addition of various functions. However, due to the limitations of the CAD system architecture developed 30 to 40 years ago, the CAD to support the shipbuilding process innovation is impossible or lacking, such as the concurrent parallel design and integrated common database that the CAD system needs to maximize productivity. As a tool, it did not meet the requirements and now imports a general-purpose CAD system developed in foreign countries and uses it according to the shipbuilder's situation. Currently, it is used by TRIBON solution of Aviva. It is a multinational company that has secured the technology and supports technology to 85% of the world's 20 largest shipbuilders, and more than 90% of Korea's medium and large shipbuilders use Aviva's design software TRIBON solution when designing ships.

The prior art related to the present invention is as follows.

Korean Patent Registration No. 10-0634639 (Registration date: October 10, 2006) uses the linear information and section information, which is the design information of the initial design time of a ship without a CAD model, to determine the structure and vibration of the entire structure of the ship regardless of ship type. It is published about how to create wire structure and vibration analysis models for analysis.

Korean Patent Registration No. 10-0666789 (Registration Date: 2007.01.03) developed a model exchange method that uses the Unified Ship Modeling for Analysis (USMA) and modeling commands that are not neutral files directly as a common model suitable for detailed design and analysis environment in shipbuilding. Generation of computer-edged engineering models using computer-edged design models applied to ship design and analysis environments to create an environment that makes efficient use of model information from different types of ship CAD systems in various CAE systems It is published about the system and its method.

Republic of Korea Patent Registration No. 10-0762368 (Registration date: September 20, 2007) in the initial design method of the ship to calculate the main items required for the initial design of the vessel based on the data input through the design interface, to set the propulsion system of the vessel The method may include inputting a premise item of a ship corresponding to the propulsion system, calculating and estimating a main item of a ship based on the input premise item, and outputting the estimated data value through an output unit. It is published about the initial design method of the ship, characterized in that.

In Korean Patent Publication No. 1- = 2008-0004058, in order to design ship design, the owner comment request (OCR) is applied by reflecting this in advance when preparing the building specifications at the order stage through the database management of the ship owner's propensity. Minimize and establish quality standards that can be shared between ship owners and shipyards, while securing departments to be technically responsible for Owner Comment Reguest (OCR) and Class Comment Request (CCR). It is published on how to build a ship design promotion planning system that can increase the height, integrate the structural strength analysis and anti-vibration work of the vibration part and the hull design part, and secure a specialized organization for the design of the cabin.

In Republic of Korea Patent Publication No. 10-2008-0004059, in the design work related to ship design, minimize the trailing owner change request (OCR) by reflecting this in advance when creating the building specifications in the order stage through the database management of the owner's propensity Establish quality standards to empathize with ship owners and shipyards, and secure departments to technically handle ship owner change requests and class comment requests (CCRs) to enhance response to ship owners, and vibrate parts and hull design parts. It is published how to build a ship design progress management system that integrates the structural strength analysis and vibration prevention work of a ship and secures a professional organization in charge of cabin design for cabin design.

Republic of Korea Patent Registration No. 10-854660 (Registration date: 2008.08.21) in the GUI environment, the related information of the cabin design of the design of the design, the captain (piping and steel) design, the design of the design and the design of the design of the research and development program to form a single program It is published about integrated system and method of numerical and quantity calculation program for designing ship design to improve the workability by designing ship design.

Korean Patent Registration No. 10-0911501 (Registration Date: Aug. 3, 2009) shows a 3D drawing directly on the spot without reworking it in 2D for a drawing modeled in 3D when creating an electronic draft of a ship design. It is published on how to create a ship design electronic drawing for ship building in a shipyard that can save time and material resources by omitting the reprocessing process into 2D information.

Republic of Korea Patent Publication No. 10-2009-0036354 (registration date: 2009.04.14) in the database to manage the power load factors of each equipment, and based on this, it is possible to create a PPD drawings and CDP drawings, thereby reducing drawing errors and M / H loss A drawing generating apparatus and method are disclosed.

However, the conventional prior arts have a variety of solutions for plants, but solutions for offshore structures and other structures utilize general general CAD.

In addition, the related arts of the related art have no idea about the function that can solve from the first project management to the 3D CAD modeling, the drawing generation, and the report on the total requirements in one CAD. It is not described or mentioned.

The technical problem to be solved by the present invention in order to solve the above problems, from the first project (Project) management to 3D CAD modeling (Modeling), drawing generation and report on the total requirements (CAD) The present invention provides a method of designing and integrating offshore structures that can be solved by a computer system and a recording medium storing computer programs for the method.

In addition, another technical problem to be achieved by the present invention is a method of designing and integrating an offshore structure and a computer program for storing the method, which provides a more convenient and stable, core custom design technology, and an enlargement and an advanced technology. To present the medium.

In addition, another technical problem to be achieved by the present invention is to arrange and combine a predefined general structural member (steel, concrete, aluminum, custom member) on the computer to assist in accurately predicting the shape after construction before construction This paper presents a method of designing and integrating offshore structures and recording media storing computer programs for the methods.

In addition, another technical problem to be achieved by the present invention is to increase the work efficiency by reducing the time of technical consultation with other fields through the integration of the drawings automatically extracted from the three-dimensional structural model with the three-dimensional design model of other fields The present invention provides a method of designing and integrating offshore structures and recording media storing computer programs for the methods.

In addition, another technical problem to be achieved by the present invention is the user wants the data to support the various tasks involved in the material cost extraction, grasping the list of members, the total cost, such as material costs for construction work, creating the process table (for example, , EXCEL file format, which can be automatically extracted from 3D design data, suggests a method for designing and integrating offshore structures that can be expected to reduce construction time, and a recording medium storing computer programs for the method. .

In addition, another technical problem to be achieved by the present invention is to provide a marine structural design and integration method for providing steel three-dimensional design data that can be used directly in the production drawing design software and a recording medium storing a computer program for the method have.

In addition, another technical problem to be achieved by the present invention is integration with industry-standard structural analysis software such as MIDAS, GT STRUDL and STAAD Pro.It can automatically link modeling data with structural analysis data. It suggests a method of designing and integrating offshore structures that can be automatically reflected in other data if changed, and a recording medium storing computer programs for the method.

As a means for solving the above-described technical problem, the invention as set forth in claim 1, "A marine structure design and integration method comprising the steps of: (a) installing and driving a marine structure design and integration program in a PC; (b) Through the offshore structure design and integration program, set basic data for setting and calculating block-related data for each construction, select materials used in each construction, set default materials for construction, and Adding a basic joint type to be used, setting dimension information and welding information for each added joint type, and storing and managing the set construction file in Excel; And (c) through the offshore structure design and integration program, create a shaped steel member, plate member, built-up member, seam and weld line in the member, Create fillets, scallops, chamfers, and bevels at the edges of the members, and slots, snips, holes, and joints in the members. (Joint), the step of generating the member information; characterized in that it provides from the first project (Project) management to 3D CAD modeling, drawing generation and reports on the total requirements through a single program Offshore structure design and integration methods.

The invention according to claim 2, wherein the marine structure design and integration program comprises: a construction opening tool for opening a construction to be set by inputting or selecting a construction number; A construction registration tool for registering a construction by entering or selecting a construction number; A construction deletion tool for inputting or selecting a construction number to be deleted and entering a password to delete the construction; A construction setting completion tool for setting the open construction; A block code generation tool for importing an Excel file that creates block codes to be added and storing them in a DB; A master block code reload tool for updating newly added or deleted block code in a master block code to a block code table of the project and block setting program; And an exit tool for terminating the program. &Quot;

According to the invention of claim 3, "The marine structure design and integration program according to claim 1 is: A construction material of an open construction is registered and unregistered as a construction material in color, change the default material and add construction materials and A material setting tool for deleting a registered construction material; A bevel setting tool for inputting bevel data required for each construction; And a section management tool for registering and deleting section steel required for each construction, generating and registering an XML file, and modifying the registered XML file. &Quot;

According to the invention as claimed in claim 4, "The marine structure design and integration program according to claim 1 includes: when performing a joint selection for the first time in a current project or when a joint type is not registered, an empty list is displayed, A joint setting tool for displaying the registered joint type in the list when the joint type is registered, setting the size and welding information of the joint type selected in the joint list, adding and registering the joint type, and deleting the joint type. Offshore structure design and integration method.

According to the invention of claim 5, “The marine structure design and integration program according to claim 1, wherein: when the control block code is selected with the construction file open, the MTO of the control block is displayed and the Excel save button is input. An MTO tool that specifies a directory and file name and outputs it to Excel; And when selected by the item to be viewed with the construction file open, the corresponding weight & COG report is printed out, and when the save button of Excel is input, the directory and file name are designated and the weight is output to Excel. & COG tools; < / RTI >

According to the invention of claim 6, "The marine structure design and integration program according to claim 1 includes: a steel member required for modeling by receiving items including a steel grade, a material, a steel grade size, a large size, and a small size type from a user. A profile generation tool; A plate generation tool for receiving an item including a steel grade, a material, a steel grade size, a large diameter, and a small diameter from a user and generating a plate member for modeling; A built-up generating tool for generating a built-up member that cannot be created with a steel or plate member and storing it as an Excel file; A cone & pipe generation tool for generating cones and pipes that are built-up members that cannot be created by members; A seam generation tool for generating seams and weld lines in the member; A pipe seam generating tool for generating a seam in a forming direction in a pipe of a section steel; A profile change / restore tool for changing the steel grade, material, and size of an existing profile and restoring the changed profile to an initial state; A fillet generating tool for generating an edge portion of the member into a fillet; A Scallop generation tool for generating an edge portion of the member as a scallop; A Chamfer generation tool for generating an edge portion of the member as a chamfer; A bevel generation tool for beveling an edge portion of the member; A slot generation tool for generating slots in the member; A cut snip generation tool for generating snips in the shape of an H beam, a channel, and an angle of the member; A hole extrude tool for creating a hole in the member; A hole array generation tool for generating holes of various shapes including rectangular and circular in the member; A drain hole and a vent hole generation tool for generating a drain hole and a vent hole in the member; An Outfit Hole generation tool for creating a pipe hole and a cable hole in the member; A standard joint generation tool for generating cutbacks and welding lines of the parent member and the child member; A standard joint restoration tool for restoring the jointed member to the state before the joint using a standard joint tool; And a member information tool for allowing a user to check the member information created or modified. &Quot;

The invention according to claim 7, further comprising: a welding creation tool for creating a welding line between two adjacent members and registering a welding property to be managed in the welding; A welding modification tool for modifying welding information of the generated welding line or deleting the welding line; A welding separation tool for correcting welding information of the generated welding line or deleting the welding line; A welding joining tool for selecting two welding lines which are in contact with each other and joining them into one welding line; A welding check tool for checking a place where a welding line does not exist in the members in contact with each other and a place where the welding line is separated from the magnetic member; And a welding information tool for displaying the welding data of the selected welding line in a list and correcting the welding data. &Quot;

The invention as set forth in claim 8, wherein the marine structure design and integration program comprises: creating and editing a type and description of a collating block, a collating block code, a block stage, an upper block code, and a block. A block code management tool for adding, deleting, and editing information such as code descriptions; A block allocating / releasing tool for allocating and releasing blocks in the absence of a design file corresponding to the selected block number; Zone creation tool for creating, modifying, and deleting zone data; And a PBS tree tool that displays the block structure of the project currently being worked on and the members belonging to the tree and displays the welding number in the weld tree at the bottom when the welding is present when selecting the parts and members. Offshore structure design and integration methods.

The invention according to claim 9, wherein the marine structure design and integration program comprises: a preliminary procedure for creating a DAT assembly flow chart, an assembly sequence designation tool for assigning the assembly sequence of each block; A block tree diagram creation tool for creating a block tree diagram; A quantity summary table creation tool for creating a quantity summary table; And an assembly point drawing drawing tool for creating an assembly point drawing. &Quot;

The invention as set forth in claim 10, further comprising: an anode tool for modeling an anode for calculating a welding quantity of an accessory anode; A HandGrip tool for modeling a handgrip to calculate a weld quantity of an accessory HandGrip; A StdLug tool for modeling StdLug to calculate the welding quantity of the accessory StdLug; A handrail tool for modeling the handrail to calculate a welding quantity of an accessory handrail; Ladder tool for modeling the ladder to calculate the welding amount of the accessory Ladder (Ladder); And a stair tool for modeling a stair. &Quot;

The invention according to claim 11, wherein the marine structure design and integration program comprises: a check-in tool for reading and processing attribute information of members and welds belonging to a block file currently being worked on and storing them in a database; A project / block matching tool for matching the project code of the member and the block code if the current construction project code and the block code are different; A regeneration tool for sequentially reassigning temporary part numbers; A drawing number matching tool for matching registered drawing numbers and connecting member numbers with each other in modeling and updating necessary values in a database; And a welding confirmation tool for matching the registered welding number and connecting member number with the welding information on the modeling and updating necessary values in the welding data. &Quot; .

In addition, as a means for solving the above-described technical problem, the invention described in claim 12, "A recording medium storing a computer program for the marine structure design and integration method according to any one of claims 1 to 11. Is provided.

The method of designing and integrating a marine structure of the present invention and a recording medium storing a computer program for the method have the following effects.

-The platform structure is automatically generated to increase work efficiency and reduce work time.

-Unnecessary cost can be reduced by automatic quantity calculation and cost calculation in drawing design.

-Ensuring consistency and access to data can increase work efficiency.

-By adding security functions, it is easy to protect data both internally and externally.

-The budget saving effect can be increased from the annual drawing outsourcing, and the design time can be shortened.

-By arranging and combining predefined general structural members (steel, concrete, aluminum, user-defined members) on the computer, it helps to accurately predict the shape after construction before construction.

-Drawings automatically extracted from 3D structural models can be expected to increase work efficiency by shortening the time for technical consultation with other fields through integration with other 3D design models.

-Automatically from 3D design data in the format desired by the user (usually EXCEL file) to support various tasks involving material extraction, material list for construction, gross weight, material cost for construction, and process table creation. As it can be extracted, it can be expected to shorten the drying time.

Steel 3D design data can be used directly in production drawing design software.

-Integration with industry standard structural analysis software such as MIDAS, GT STRUDL and STAAD Pro. Can automatically link modeling data with structural analysis data. It is possible to reflect.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Hereinafter, specific technical contents to be implemented in the present invention will be described in detail with reference to the accompanying drawings.

Embodiment of Offshore Structure Design and Integration System

1 to 2 is a schematic diagram of a marine structure design and integration program according to a preferred embodiment of the present invention, Figure 1 is a functional diagram of the project and the block setting program, Figure 2a to 2c is a marine structure design and integration It is a functional diagram of each program.

First, as shown in FIG. 1, the project and block setting program may be divided into a project unit 110, a default unit 120, a joint unit 130, and a report unit. 140.

The project unit 110 is an air opening tool 111 for opening a construction set by inputting or selecting a construction number, a construction registration tool 112 for registering a construction by inputting or selecting a construction number, and a construction to be deleted. The construction registration tool 113 for entering or selecting a number and entering a password to delete the construction, the construction setting completion tool 114 for completing the setting of the opened construction, and an Excel file in which the block code to be added are created. Block code generation tool 115 for loading and storing in DB, and master block code reload for updating newly added or deleted block code in master block code to block code table of the project and block setting program. Tool) 116, and an exit tool 117 for terminating the program.

The default unit 120 is a material setting tool 121 for displaying a registered and unregistered situation as a construction material of an open construction in color, changing a default material, adding a construction material, and deleting a registered construction material. And a bevel setting tool 122 for inputting bevel data required for each construction, and a beam for registering and deleting section steel required for each construction, generating and registering an XML file, and modifying a registered XML file. It consists of the management tool 123.

The joint unit 130 displays an empty list when the joint is first selected in the current project or when the joint type is not registered, and the joint type registered when the joint type is registered in the current project. It is comprised by the joint setting tool 131 which displays to a list. The joint setting tool 131 includes a function of setting dimensions and welding information of a joint type selected from a joint list, adding, registering, and deleting a joint type.

The report unit 140 displays the MTO of the check block when the check block code is selected in the state in which the construction file is opened, and designates a directory and a file name when the save button of Excel is input, and outputs it to Excel. (141) And, if the construction file is selected by the item to be viewed in the open state outputs the corresponding weight (Weight) & COG report for each item, and if the Excel save button is input, specify the directory and file name and output the output to Excel (Weight) & COG tool 142.

The project and block setting program sets basic data for each construction and block-related data calculation, selects materials used in each construction, sets default materials for construction, adds basic joint types to be used in each project, and This function sets dimension information and welding information for each joint type added and saves and manages the set construction file in Excel.

As shown in FIGS. 2A to 2C, the offshore structure design and integration program includes a member generation unit 210, a welding function unit 240, a block management unit 250, a report function unit 260, and a DAP unit ( 270, an accessory unit 280, and other functional units 290.

The member generating unit 210 includes a profile generating tool 211, a plate generating tool 212, a built-up generating tool 213, cones, and pipes. Generation tool 214, seam generation tool 215, pipe seam generation tool 216, profile change / restore tool 217, fillet generation tool 218, Scallop generation tool 219, chamfer generation tool 220, bevel generation tool 221, slot generation tool 222, cut snip generation tool 223 Hole Extrude Generation Tool 224, Hole Array Generation Tool 225, Drain Hole & Vent Hole Generation Tool 226, Outfit Hole (Outfit Hole) generation tool 227, standard joint generation tool 228, standard joint restoration tool 229, and the member information tool 230.

Here, the profile generation tool 211 performs a function of generating a steel member required for modeling by receiving items including a steel grade, a material, a steel grade size, a large diameter, and a small diameter from a user.

The plate generation tool 212 receives a function including a steel grade, a material, a steel grade size, a large diameter, and a small diameter from a user to generate a plate member for modeling.

The built-up generating tool 213 performs a function of generating a built-up member which cannot be generated as a steel or plate member and saves it as an Excel file.

The cone & pipe generation tool 214 can generate cones and pipes that generate cones and pipes that are built-up members that cannot be created as members. Do this.

The seam generation tool 215 performs a function of generating a seam and a welding line in the member.

The pipe seam generating tool 216 performs a function of generating a seam in a forming direction in a pipe of a section steel.

The profile change / restore tool 217 changes a steel grade, material, and size of an existing profile, and restores the changed profile to an initial state.

The fillet generation tool 218 performs a function of generating an edge portion of the member as a fillet.

The Scallop generation tool 219 performs a function of generating an edge portion of the member as a scallop.

The chamfer generating tool 220 performs a function of generating an edge portion of the member as a chamfer.

The bevel generation tool 221 generates a bevel of the edge portion of the member.

The slot generation tool 222 performs a function of generating a slot in a member.

The cut snip generation tool 223 generates a snip in the shape of an H beam, a channel, and an angle of the member.

The hole extrude generation tool 224 performs a function of generating a hole in the member.

The hole array generation tool 225 performs a function of generating holes of various shapes, including rectangles and circles.

The drain hole and vent hole generation tool 226 performs a function of generating a drain hole and a vent hole in the member.

The fit hole generating tool 227 performs a function of generating a pipe hole and a cable hole in the member.

The standard joint generation tool 228 performs a function of generating cutbacks and welding lines of the parent member and the magnetic member.

The standard joint restoration tool 229 performs a function of restoring the jointed member to the state before the joint by using the standard joint tool.

The absence information tool 230 performs a function of checking the absence information created or modified by the user.

In addition, the welding function unit 240 is a welding generation tool 241, a welding modification tool 242, a welding separation tool 243, a welding coupling tool 244, a welding check tool 245, a welding information tool 246 ) Is included.

Here, the welding creation tool 241 generates a welding line between two adjacent members and registers welding properties to be managed in the welding.

The welding modification tool 242 performs a function of correcting the welding information of the generated welding line or deleting the welding line.

The welding separation tool 243 performs a function of correcting welding information of a generated welding line or deleting a welding line.

The welding coupling tool 244 selects two welding lines which are in contact with each other, and combines them into one welding line.

The welding check tool 245 performs a function of checking where a welding line does not exist in a member in contact with each other and where a welding line is separated from a magnetic member.

The welding information tool 246 displays welding data of the selected welding line in a list and performs a function of modifying welding data.

In addition, the block manager 250 includes a block code management tool 251, a block allocation / release tool 252, a zone creation tool 253, and a PBS tree tool 254.

The block code management tool 251 creates and edits the type and description of the check block, and adds, deletes, and edits information such as check block code, block stage, upper block code, and block code description of the check block. To perform.

The block allocation / releasing tool 252 performs a function of allocating and releasing blocks in the absence of a design file corresponding to the selected block number.

The zone creation tool 253 performs a function of generating, modifying, and deleting zone data.

The PBS Tree tool 254 displays the block structure of the project currently being worked on and its members as a tree, and displays the welding number in the welding tree at the bottom if there is a welding when selecting the parts and members. do.

The report function unit 260 also includes an MTO tool 261.

The MTO tool 261 performs a function of providing an MTO or a weight & COG report for each control block of an open construction in a state in which a construction file is open, and storing and outputting it in Excel.

The DAP unit 270 includes an assembly order designation tool 271, a block tree diagram creation tool 272, a quantity summary table creation tool 273, and an assembly procedure diagram creation tool 274.

Here, the assembling order designation tool 271 performs a preliminary process for creating a DAT assembling flow chart, and assigns an assembling order to each block.

The block tree diagram creation tool 272 performs a function of creating a block tree diagram.

The quantity summary table preparation tool 273 performs a function of creating the quantity summary table.

The assembly instruction diagram creation tool 274 performs a function of creating an assembly instruction diagram.

In addition, the accessory unit 280 may include an anode tool 281, a hand grip tool 282, a StdLug tool 283, a handrail tool 284, and a ladder tool ( 285, a stair tool 286 is included.

Here, the anode tool 281 performs a function of modeling the anode in order to calculate the welding quantity of the accessory anode.

The handgrip tool 282 performs a function of modeling a handgrip to calculate a welding quantity of an accessory handgrip.

The StdLug tool 283 functions to model StdLug to calculate the welding quantity of the accessory StdLug.

The handrail tool 284 performs a function of modeling the handrail to calculate the welding quantity of the accessory handrail.

The ladder tool 285 performs a function of modeling a ladder in order to calculate a welding quantity of an accessory ladder.

The stair tool 286 performs a function of modeling a stair.

Finally, the miscellaneous function unit 290 includes a check-in tool 291, a project / block matching tool 292, a regeneration tool 293, a reference number matching tool 294, and a welding confirmation tool 295. ) Is included.

In this case, the check-in tool 291 performs a function of reading, processing, and storing the attribute information of the member and the welding belonging to the block file currently being worked on, in a database.

The project / block matching tool 292 performs a function of matching the project code and the block code of the member when the current construction project code and the block code are different.

The regeneration tool 293 performs the function of sequentially reassigning the temporary part number.

The drawing member number matching tool 294 performs a function of matching registered drawing numbers and connecting member numbers with each other in modeling and updating necessary values in a database.

The welding confirmation tool 295 performs a function of matching the registered welding number and the connection member number with the welding information on the model and updating necessary values in the welding data.

Project

3 is a project menu screen on the main screen of the project and block setting program 100.

The main screen of the project and block setting program 100 includes a project, a default, a joint, and a report menu as shown in the screen of FIG. 3.

Here, the Project menu is in charge of the basic setting for calculation of each construction and block-related data, opening construction, construction registration, construction deletion, construction setting (complete), Block Code (Block Code) Generation and master block code reload.

Clicking [Open Construction] on the Project menu displays the Construction Heat Value Window. After entering or selecting a construction number in the construction opening window and clicking the [Open construction] button, a screen in which construction to be set is opened is displayed.

Click [Register Construction] on the Project menu to display the construction registration window. After entering or selecting a construction number in the construction registration window, click the [Register] button. At this time, when the construction registration is completed, a construction registration confirmation window appears.

Click [Delete Construction] on the Project menu to display the Delete Construction window. Input the construction number to be deleted in the construction deletion window and click the [Delete construction] button, a window for entering a password appears. Enter your password and click OK and you will be asked if you want to delete the project again. At this time, if you click the [Yes] button, the corresponding construction is deleted.

Click [Completion Setting] in the Project menu. If there is no open construction, an error window occurs. If the setting is completed in the window asking for completion, click the [Yes] button to complete the construction setting.

Click [Block Code] from the Project menu. Click the [Add Block ...] button to load the Excel file that created the block code to add.

Check the added block code and click the [Generate] button. The added block code is stored in the DB. At this time, the block code loaded from the Excel file is displayed in red on the screen.

Clicking [Master Block Code Reload] in the Project menu brings up a window for comparing the Master Block Code and the GH Structural Block Code. The block code newly added in the master is displayed in red, and the block code deleted in the master is displayed in gray in the GH Structural Block Code window. Click the [Block Code Update] button at the bottom of the screen. The GH Structural Block Code Table is updated.

Default

4 is a screen of a default menu on the main screen.

As shown in the screen of FIG. 4, the default menu includes materials, bevels, and section steel management items.

Here, the material serves to select a material used in each construction and set a default material for construction.

Click [Material] on the Default menu. Here, if there is a material set as the default (Default), it is displayed in purple. Materials applied for construction of open construction are blue, and materials not registered as construction materials are displayed in gray letters.

If you want to change the default material, check the material to be changed and click the [Default Material Settings] button. A window appears asking if you want to change the default material. If you click the [Yes] button, the default material is changed.

If you want to add materials for construction, select singular or plural materials shown in black and click the [Add Public Materials] button. If the color changes to blue on the screen, it is registered as a construction material.

Select one or more materials to delete among the materials registered as construction materials and click the [Delete Public Materials] button. If the color changes to black on the screen, it is deleted from the construction material.

Next, the bevel function for inputting bevel data required for each construction will be described.

Click [Bevel] on the Default menu. However, the construction to be set should be set. If bevel is set in the relevant construction, the stored value is loaded. If the value is saved, enter the new bevel value and click the [Save] button.

Finally, the section management is responsible for registering the section steel required for each construction.

Click [Management Steel] on the Default menu and select the steel type to be registered as construction steel. The section steel currently registered as construction section is marked in blue. If you select the section steel to add and click [Register steel grade] button, it will be additionally registered as construction section steel.

Steel class registration can be deleted from the steel grades for construction by selecting the steel beams to be deregistered among the steel grades registered as construction steels and clicking the [Register Steel Grades Unregistered] button.

In the section management, the XML generation is clicked on the "Generation XML" button after registering the construction section steel. In the case of a new generation, create an XML file, and if an existing generated XML file exists, check whether or not to overwrite it. After selecting the [Yes] button and generating the XML, check whether the generated file is checked. If you select the [Yes] button, you can check the fished XML file.

The method of registering the generated XML file is as follows.

Before creating a new project in ProjectWise, modify the environment variable of 'Application' and 'Project' environment variable in ProjectWise Administrator.

Copy the other environment variables from the 'application' environment variable and modify the 'name' and description '. For example, copy DEV2 and modify the name and description to '1005'.

Copy the 'application' environment variable as it is, and modify only the 'name' and 'description' environment variables, leaving other environment variables unchanged.

Copy the 'project' environment variable in the same way as the 'application' environment variable and then modify the 'name'. For example, copy '7777' and rename it to '1005'.

Go to the Properties → Variables tab of the copied 'Project' environment variable and modify PROJECT_CODE and STRUCTURAL_SHAPES.

㉠ Change PROJECT_CODE = 7777 to PROJECT_CODE = 1005

㉡ Change STRUCTURAL_SHAPES = 7777.xml to STRUCTURAL_SHAPES = 1005.xml

After creating a new project (1005) in ProjectWise, add the environment variable created by ProjectWise Administrator to 'Application' and 'Project' in the Properties → Workspace tab.

Put the newly created 1005.xml in the ProjectSetting folder in the ProjectWise folder. If you open the DGN file in the new project (1005), you should check that it comes in '1005.xml'.

For reference, there are various variables related to ProjectWise project in 'Application' environment variable or 'Project' environment variable of ProjectWiseAdministrator, and each variable can be changed. The above example is an example of setting environment variables for XML registration.

Joint

5 and 6 are execution screens of the joint setting menu in the main screen, FIG. 7 is a setting list screen for each type in the joint setting menu, and FIG. 8 is a welding line setting screen in the joint setting menu.

Joint function adds basic joint type to use in each project, sets dimension information and welding information for each added joint type, and standard joint modeling tool. ) To facilitate the use.

When the joint type is not registered or when the joint type is registered for the first time in the current project, a joint setting execution screen as shown in FIG. 5 is output. If a joint is selected for the first time in the current project or a joint type is not registered, an empty list appears.

And joint type (Joint Type) is registered In this case, a joint setting execution screen as shown in FIG. 6 is output, and when a joint type is registered in the current project, the registered joint type appears in the list.

Joint setting method is as follows.

Click [Joint] in [Joint] of the menu. At this time, it is possible to select [Joint] only by opening the project in the open project in the menu of the menu. If you execute [Joint selection] for the first time or the joint type is not registered, the list will be blank.

If a Joint Type is registered If you select [Joint Selection], the registered Joint Type is displayed in the list. Here, a joint type automatically marked with a shank in a joint type list means that a dimension value or welding information of the corresponding joint type is not set.

The joint type setting is used to set the size and welding information of the joint type selected from the joint type list.

Left-clicking on the check box of each joint type in the Joint Type list selects the corresponding joint type, and clicking the left mouse button once again deselects it.

Clicking Select All selects all Joint Types in the Joint Type list. Clicking once again deselects all selected Joint Types. After selecting the Joint Type and clicking the [Set by Type] button, a list of settings by type will appear.

'STD_01, STD_05, STD_11, STD_28' selected in the joint type selection are displayed in the joint type list. The image of the selected joint type and the dimension setting for each type are displayed in the joint type list, and the dimension value to be input is input. If the dimension value appears in the dimension setting for each type, it means that there is a previously registered value. If you click 'OK', the dimension setting value for each type is saved.

To set the welding line, click the [Welding Line Setting] button in the << Setting List by Type>. Then, select welding code and welding code for each welding line and click 'Save' to save the selected welding information.

Joint type addition function is executed by clicking [Add Joint Type] button. When a joint type is registered, all joint types are displayed except for a joint type that is registered. If a joint type is not registered, all joint types are displayed.

If you click the Select All button, all the types of [Add Joint Type] will be checked. If you click it again, all of the check marks will be cancelled. Check the Joint Type to add and click the 'OK' button to add the Joint Type.

Since the added joint type simply adds a joint type, the dimension type and the welding information must be set through [type by type].

Two types of 'STD_02, STD_06' selected in Add Joint Type are added. Since only the Joint Type is added, it is automatically checked in the [Select Joint Type] list. The meaning of the shank display means that the dimensioning or welding information of the joint type has not been saved.

The Type Delete function is executed by clicking the [Delete Type] button.

The currently registered joint type appears in the [Delete Joint Type] list. If you click the Select All button, all the types of [Delete Joint Type] will be checked. If you click it again, all of the check marks will be cancelled.

Check the Joint Type to delete and click the 'OK' button to delete the Joint Type. The deleted Joint Type can be added again using [Add Joint Type].

When a new joint type is added to the standard joint modeling tool, a new joint type added in modeling is added to register the joint type in the default setting. Should be added.

Additional items should include Joint Name, Number of Welding Lines, Dimension Symbols to be Used, Joint Image, and Welding Line Image. Left-clicking on an image field brings up a dialog box for opening the image. Three image formats are available: JPEG, BMP, and GIF. When entering dimension symbols, the separator between symbols should be ','.

Usable dimension symbols are 'a (a1), a2, d, f (f1), f2, g (g1), g2, h (h1), h2, l, R, T, w (w1), w2' . When the input item is completed, click [OK] button to add it to the database.

Report

9 and 10 are MTO, Weight & COG execution screen of the Report menu on the main screen.

First, the MTO screen of FIG. 9 is an MTO screen for each control block of the currently opened construction.

The control block combo box is the control block number of the currently open construction, and the view combo box is a function that can be viewed by All, Plate, and Profile.

The method of use is that the construction must be open to see the MTO by contrast of the construction. If you select the collation block code, you can see the MTO of the collation block. If you need to output to Excel, press the Excel save button, specify the directory and file name to save, and output it to Excel.

The weight & COG screen of FIG. 10 is a screen of weight & COG according to the contrast of the currently open construction, each block of heavy water, and a large construction type. You can see the weight & COG of the item you want to see as a control block combo box, a heavy-duty block combo box, and a large industrial combo box.

In order to view the Weight & COG Report of the relevant construction, you must open it and open the construction to see the Weight & COG Report. If you select by item (control block, heavy block, large type) in open construction, you can see Weight & COG Report for each item and if you want to output to Excel, you can check the data by pressing the Save as Excel button. Do.

Profile Creation Tool (211)

11 is a screen of a profile generation tool 211.

The profile generation tool 211 performs a function of generating a steel member required for modeling.

The screen configuration of the profile creation tool 211 is a steel combo box, material combo box, size combo box, large work combo box, small work combo box, temporary member number text box, Global X, Y, Z Offset text box, Cardinal Point image box, Rotation Angle text box, Part placement point combo box, [place] button, [Close] button It is included.

The steel grade and size selection is made by selecting a steel grade desired by the user in the steel grade combo box, and selecting a project registration size corresponding to the selected steel grade by the user in the size combo box.

Material selection selects a material desired by the user from the material combo box. By default, the default material selected in Project Setting is displayed when the program is first run.

Large species selection selects the large species for the generation member in the large species combo box. Since small pore species are automatically input according to the large species selected by the user, the small member species are selected from the small pore combo box.

The temporary member number text box inserts a temporary member number into the generation member. The user can enter it manually, but the number of temporary member numbers automatically increases each time a member is created.

The global X, Y, Z offset text box moves the member by the X, Y, Z offset value from the first point clicked by the user to the global coordinate.

The cardinal point image box generates a member after a user selects a desired cardinal point. The cardinal point of the member can be checked by the position of PPoint and QPoint generated after selecting the member.

If a rotation is to be given to the generating member, it is generated after inputting a value in the Rotation Angle text box.

In the member arrangement point combo box, [TwoPoint] places the member by the user taking two points, and [Length] indicates the direction (X, Y) after the user inputs the profile member length in the text box. Use ComboBox to select whether or not it is to be located with (Z). The select path selects a path where the profile member is to be placed and clicks to place the profile member.

The user can input and select before adding the profile member: steel grade, material, steel size, large size, small size, temporary part number, offset (X, Y, Z), CP, R.Angle . Among these items, it is essential to add a profile member to select steel grade, material, grade size, large size, and small size.

㉠ Select PlaceBy (Two Point) → click Place → create Profile member

Tap the first point, select the point you want to place, and click the second point to place the member at the point you want.

㉡ Select PlaceBy (Length) → click Place → create Profile

After inputting the corresponding length and defining the X, Y, and Z axes, the user selects the placement position (see FIG. 12C). Placement location is selected and click to place on user location.

㉢ Select PlaceBy (Select Path) → click Place → Create Profile

When the desired figure is selected, the member is arranged to match the position and length of the selected member.

Plate Creation Tool 212

12 is a screen of a plate generation tool 212.

The plate generating tool 212 performs a function of generating a plate member necessary for modeling.

The screen configuration of the plate generating tool 212 is a steel combo box, a material combo box, a large combo box, a small work combo box, a temporary member number text box, and a plate tab as shown in the screen of FIG. 12. , Arc Tab, Plate Extrude Tab, Circle Extrude Tab, Flood Circle Extrude, Thickness Textbox, Offset (Offset) Includes a selection combo box, Side Angle combo box, [Place] button, and [Close] button.

Here, the plate tab is a tab for generating a plate member after the creation point is clicked, and the arc tab is a start point, a center point, and an end point. ) Click to create an arc member, and the plate extruding tab (Plate Extrude Tab) is extruded in shape after clicking shape, complex shape A tab for creating a member, the circle extrude tab is a tab for generating a member by clicking the circle and then extruded in a circular shape (Flood Circle tab) Extrude is a tab that clicks on a line, shape, ellipse, or complex shape, and extrudes the member to create a member.

How to use the plate generation tool 212 is as follows.

1) Select Plate Tab → click [Place] button → Create plate member

①Input Variables: Thickness, Offset: Upper, Middle, Lower, SideAngle

Click on the creation points of the desired shape.

플레이트 One plate is created with the position of clicked point

②When selecting Side Angle and inputting Angle value

Click on the creation points of the desired shape.

Create plate by inputting positive or negative angle value

2) Select Tab (Arc) → click Place → create Arc member

①Input variables: Height, Offset (Up, Middle, Down), Width

클릭 Click the start, center, and end points of the desired shape

Plate Plate is created according to the entered height and width.

3) Select Tab (Plate.Ex) → click Select button → Create Plate.Ex member

①Input variables: Thickness, Offset (Up, Middle, Down), SideAngle

② SideAngle is the same as Tab (Plate)

Click the shape of the shape to extrude the plate.

클릭 Click again to create a plate in the shape of the first click.

4) Select Tab (Circle.Ex) → click the Select button → create Circle.Ex member

①Input variable: Height, Offset (Up, Middle, Down)

Click on the shape of the plate to extrude the plate.

클릭 Click again to create a plate based on the clicked circle.

5) Select Tab (Flood.Ex) → click Place → create Flood.Ex member

① Input variables: Height, Offset (up, middle, down), Knuckle check, Knuckle count

Click the shape of the shape to extrude the plate.

Click on the inner area of the shape to extrude again to create a plate based on the clicked shape.

② When creating Knuckle member

Knuckle check is done when rebuilding Knuckle.

Ⓑ Knuckle number inputs the number of times the knuckle member is bent.

ⒸKnuckle check, Knuckle count is used for unit calculation

After checking Knuckle and inputting Knuckle count, click the corresponding figure.

Click on the inner area of the shape to extrude again to create a plate based on the clicked shape.

③ When creating a hole member

Ⓐ Members can't be created through hole.

Ⓑ Hole should be created using Hole Tool

PlateGenerate plate by Flod Extrude method

㉡A warning sentence is displayed and click OK.

Plate Plate without hole is created

Built-Up Generation Tool (213)

13 is a screen of the user input tab Tab of the built-up generating tool 213.

The built-up generating tool 213 performs a function of generating a built-up member that cannot be formed by a steel or plate.

The screen configuration of the built-up generation tool 213 is a built-in type combo box, a material related item combo box, a cardinal point image box, and a large work combo as shown in FIG. 13. Box, Small Work Combo Box, Temporary Part Number Text Box, Graphic Group Selection Check Box, User Input Tab (Tab), Part Welding Tab (Tab), Excel Input Tab (Tab), [ExcelSave] Button, [Place] Button And [Close] button.

The user input tab is configured to input or select a user value input item and an image for each built-up type.

When the user changes the built-up type, the image of each built-up type, the C.P image, and the user value input items are changed. There are six built-up types: I, H, L2, L3, BOX1, and BOX2.

The material-related item combo box displays an individual member number to be generated for each built-up type. The combo box of the material selects a material to be inserted into the selected individual member number. Individual part numbers are displayed in a built-up image.

The Graphic Group check box may include a method of checking and creating a graphic group or a graphic group without checking.

The large, small, temporary member number, rotation is the same as the profile (Profile).

To save the built-up Excel file, click the [ExcelSave] button on the user input tab, and an Excel file save window is created in the program setting folder.

Program setting folder is 'C: \ 3DFOS \ BuiltUp \ Construction Number', and the Excel file name is 'BU' + Construction number by default. Click the Save button to save the file as an Excel file. At this time, several built-up items can be stored in one Excel file.

14 is a screen of a member welding tab Tab of the built-up generating tool 213.

The screen configuration of the member welding tab (Tab) is, as shown in Figure 14, individual member welding line number combo box, welding hold check box, NDE inspection area setting combo box, weld insertion image box, [Detail welding data input] button It is included.

Here, the individual member welding line number is different for each built-up type. We have welding line of I, H type (2 pieces), L2, L3 type (1 piece), BOX1, BOX2 type (4 pieces). After selecting each welding line number, press the welding detail data input button, input the value in the welding variable input window, and click the [Confirm] button to insert the welding data.

The weld hold check checks the weld hold if you do not want to insert a weld line. The NDE inspection area setting sets three areas for the QA inspection: Primary, Secondary, and Special. The welding insertion image changes according to a built-up type selected by the user. In the welding detail data input, when a welding detail data input button is pressed, a form capable of inputting welding detail data is displayed on the screen.

Joint codes are T and FILLET. After selecting the desired joint code, the user inputs each welding data and then clicks the [Confirm] button to insert the welding data into the welding line.

Welding data (Data) can be confirmed through the welding information tool (Tool).

15 is a screen of an Excel input tab Tab of the built-up generating tool 213.

The screen configuration of the Excel input tab Tab is a combo box of a built-up type in Excel, and a built-up in Excel. It includes a size combo box, a size value display box of a selected size, a built-up identifier combo box, and a built-up image box.

To import a built-up Excel file, press the [ExcelImport] button on the Excel input page to create an Excel file open window in the program setting folder. Click the Open button after clicking the Excel file that the user wants to import.

The Excel Built-Up Type extracts and displays a Built-Up Type imported into Excel. The built-up image changes according to the selected built-up type.

The size display shows the user the size imported in Excel according to the Excel Built-Up Type selected by the user. According to the selected size, the built-up identifier and the corresponding size dimension list box are displayed.

In the Size list box, values that are imported into Excel according to the size selected by the user are displayed in the list box.

If you click ListBox once, the Excel data modification form for the size appears.

Excel Data Modification is used to modify the user-selected Built-Up Size. If you input the dimension value and press the Modify button, the dimension size is changed in the Excel file.

To create a numerical input member, click Page (user input) and input the dimensions for each built-up type. At this time, the input dimensions are built-up type (BuiltUp Type), material, large work, small work, cardinal point, graphic group (GraphicGroup), rotation (Rotation), each built-up type (BuiltUp Type) Contains a value. When entering welding data, click 'Enter welding detailed data' button for each welding number and input welding variable.

When the input of the dimensions for each built-up type is completed, a place-up member is generated by selecting PlaceBy (Two Point, Select Path) and then clicking the [Place] button.

To add an Excel input member, click Page (Excel Input), click the [ExcelImport] button, and then import the corresponding Excel file. Next, select the Excel Built-Up Type, select the size of the selected Excel Built-Up Type, select PlaceBy (Two Point, Select Path), and then select [ Place] button, the built-up (BuiltUp) member is created.

FIG. 16 is a diagram illustrating the generated built-up image. Here, yellow lines are welding lines.

Cone & Pipe Creation Tool (214)

17 is a screen of the Cone & Pipe Creation Tool 214.

The cone & pipe generation tool 214 performs a function of generating a cone and a pipe, which are built-up members that cannot be formed by the steel or plate.

The screen configuration of the cone & pipe generation tool 214 is a large combo box, a small combo box, a temporary member number text box, a material combo box, and a cone base radius (Cone Base). Radius) Text Box, Cone Top Radius Text Box, Cone Thickness Text Box, Cone Rotation Text Box, Eccentric Cone Check Box, Weld Hold Check Box, Normal and Multiple Cone SweepAngle Check and Text Box , Multiple cone generation count check and text box, Eccentric cone X, Y deviation and height text box, Eccentric cone sweep angle text box, Eccentric cone generation count combo box, Eccentric cone plate check box, Eccentric cone length text box, [Place] It includes a button and a [Close] button.

The Cone Base Radius & Cone Top Radius means two radii of each Cone, and if the Top Radius and the Base Radius are the same, the pipe ( Pipe is created.

The cone rotation is the same as the profile.

The eccentric cone check box does not check the eccentric cone when the center axis is the same, and checks the eccentric cone when the center axis is different.

If the welding hold is checked, no welding line is generated.

When the sweep angle x count is 360 or more, an error message is output. For example, if SweepAngle = 60 and Count = 7, a message is output that a cone is not created. That is, since 60 × 7 = 420, cones are not generated in excess of 360.

When the eccentric cone plate is checked and eccentric cones are generated, two plates are attached to the side of one eccentric cone. Both sides of the plate are formed by the length of the eccentric cone.

General and multi-cone member creation methods are input for each cone-related variables (T.Radius, B.Radius, Thickness, Rotation, SweepAngle and Count). After that, select PlaceBy (Select Path is Line only) and click [Place] button to create Cone & Pipe member.

Before adding eccentric cone member, the variables related to eccentric cone (T.Radius, B.Radius, Thickness, Rotation, X Deviation, Y Deviation, Height, Eccentric SweepAngle, Count, Eccentric ConePlate Check, Eccentricity) Enter the length of ConePlate, click the [Place] button and click only one point to create an eccentric cone member.

The welding line is generated when multiple cones and multiple eccentric cones are generated. If the thickness is T> 20, the welding line with the welding code 'BDCG' is created. If the thickness is T <= 20, the welding line with the welding code 'BVCB' is created (the default value). At this time, the variable values entered in each welding line can be modified in the welding modification.

Seam Creation Tool (215)

18 is a screen of the seam generating tool 215.

The seam generation tool 215 serves to generate seams and welding lines in the section steel or plate member.

As shown in FIG. 18, the screen configuration of the seam generation tool 215 may include an initialization button, a select button, a seam generation button, a welding hold check box, and welding information for inputting or selecting welding input variables. The welding input variable includes a joint type combo box, a welding code combo box, a weld length text box, a root text box, an angle of improvement text box, a gouging text box, an additional welding rate text box, and a zone. (Zone) Enter or select data in the Name combo box.

The initialization box initializes the setting when the wrong member is selected when selecting the seam generating member, and the select button is used when selecting the seam generating member and the seam element. Specify whether or not to create a seam with Multi by specifying the area for selecting individual members.

The seam button is used to create a seam based on a seam generation member and seam element selected by a user.

The welding hold check box is the same as a cone, and the welding input variable may input each welding variable based on a welding code selected by a user.

PipeSeam Creation Tool (216)

19 is a screen of a pipe seam creation tool 216.

The pipe seam generating tool 216 performs a function of generating a seam in a forming direction in a pipe of a section steel.

The screen configuration of the pipe seam generation tool 216 may include a user input angle display box, a multi pipe seam start angle text box, a seam angle text box, and a multi seam as illustrated in FIG. 19. Seam) It includes check and generation count text box, welding hold check box, and welding input variable input unit for inputting or selecting welding input variable. The welding input variable input unit includes a joint type combo box, a welding code combo box, a weld angle text box, a root text box, an angle of improvement text box, a gouging text box, an additional welding rate text box, and a zone name combo. It contains a box.

The user input angle display only shows the angle of the sweep angle in the case of a normal pipe seam. In case of Multi PipeSeam, only the angle of StartAngle is displayed, and the position of the first Seamline at StartAngle is displayed, and each SeamLine is a SweepAngle. Located far away). In this case, the seam line is generated as many as the number of multi seams.

The welding hold and welding input parameters are the same as in the Seam generation tool.

To create one seam, insert a sweep angle and click on a seam generating member. After creating the seam, input another angle, click the [Place] button, and click on the seam generating member to create a seam at another angle.

To create a Multi Seam, enter the StartAngle and SweepAngle, click on the Seam Generation Member and click on the Seam Generation Member. Is generated.

Profile Change / Restore Tool (217)

20 is a screen of the profile change / restore tool 217.

The profile change / restore tool 217 changes a steel grade, material, and size of an existing profile, and restores the changed profile to an initial state.

The screen configuration of the profile change / restore tool 217 is a steel combo box, a material combo box, a size combo box, a support mode combo box, a [select] button, and [execute]. Button and [Exit] button. The Support Mode combo box includes a change mode for changing the steel grade, material, and size of the selected profile, and a restore mode for restoring the selected profile to the initial state. Restore Mode). At this time, the steel grade, material, size can not be changed.

First, the change mode execution method selects a change mode from the support mode. Then click the [Select] button to select the member. Then select the part whose profile you want to change with the left mouse button. If you keep clicking the left hand button on the child you want to select, you can make multiple selections. If a member is selected, information on the member is displayed in the steel type, material, and size fields.

After that, change 'steel grade', 'material', 'Size' to the desired value and change / restore the profile. At this time, if you click the [Execute] button to change / restore the profile, the profile is changed.

Next, in the method of executing a restore mode, the restore mode is selected from the support mode. In the restore mode, 'steel grade', 'material', and 'Size' cannot be changed (deactivated state).

Next, click the [Select] button to select a member and select the member whose profile you want to change with the left mouse button. If you continuously click on the child you want to select with the left mouse button, multiple selection is possible, and there is no limit to the number of selections. The selected member is a member having a hole, a fillet, and a snip.

Next, click the [Execute] button to execute the profile change / restore and restore the original state where all the holes, fillets, and snips disappear.

Fillet Generation Tool (218)

21 and 22 are screens and an execution result screen of the fillet generation tool 218.

The screen configuration of the fillet generation tool 218 is composed of a Radius text box and an [Execute] button as shown in FIG.

Enter a Radius value in the Radius text box, press the [Execute] button, and select an edge to fillet. After that, when the mouse Data Button is pressed, the selected edge is filleted.

Scallop Generation Tool (219)

23 and 24 show screens of the scallop generation tool 219 and execution result screens.

The screen configuration of the Scallop generation tool 219 is composed of a Radius text box and an [Execute] button as shown in FIG.

Enter a Radius value in the Radius textbox, press the [Execute] button, and select an Edge to be scalloped. After that, when the data button is pressed, the edge is scalloped.

Chamfer Generation Tool 220

25 and 26 are screens and an execution result screen of the chamfer generating tool 220.

As shown in FIG. 25, the screen configuration of the chamfer generating tool 220 is composed of interval 1 and distance 2 combo boxes, and an [execute] button.

Input the interval 1 and interval 2 values into the interval 1 and distance 2 combo boxes. At this time, to enter a different distance value, click the key icon.

Then, press the [Execute] button and select an edge to chamfer. Click the Swap checkbox to swap the interval1 and interval2 values. After the interval values have been determined, pressing the mouse data button causes the edge to chamfer.

Bevel Creation Tool (221)

27 and 28 are screens of the bevel generation tool 221 and execution result screens.

The screen configuration of the bevel generation tool 221 is composed of a stepped text box, an improved height text box, a ratio text box, an offset text box, and a [OK] button as shown in FIG. 27.

Here, if an edge is selected for beveling without inputting a step value, a default step value and ratio for each construction are automatically entered. If there is no default step value for each construction or if you want to enter the step value manually, enter the desired value in the Step text box. Clicking the step text box displays a descriptive picture of what the step represents.

If you select Edge, the height field value is entered automatically.

As with the step value, if the user wants to enter a retrofit value, enter the desired retrofit value in the retrofit text box. Clicking on the improvement sheet text box displays a descriptive picture of what the improvement sheet represents.

If you want to bevel only one part by entering the improved field value, the bevel will work as long as the improvement distance toward the selected part with respect to the center of the selection line where the bevel is generated. When selecting the edge of the plate to bevel, the direction of the bevel is determined.

If you want to bevel a certain distance apart, you can bevel at that distance by entering the desired distance in the Offset text box.

Clicking the Offset text box will display an explanatory picture of what the offset represents.

When you have finished setting the step, enhancement, and offset values to default or custom, click the mouse data button to complete the bevel.

Slot Generation Tool (222)

29 and 30 are screens of the slot generation tool 222 and execution result screens.

The screen configuration of the slot generation tool 222 is a section type text box, a hole type text box, an image box, an A, B, C, D value text box, as shown in FIG. It includes an Edge textbox, a Select button, and a Cut Slot button.

To generate a slot, press the [Select] button and then select a plate or a steel sheet on which a slot is to be created. Since slot generation can work simultaneously, multiple selections must be made to create slots in consecutively placed plates or sections. At this time, the selection is to take the member with the mouse data button, the selection is completed, when the mouse data button is clicked in the space without the member likewise to select the members to create a slot (Slot).

Once you have selected the members to create the slots, select the section steel that passes through the members. Shape Strength Slots As with the member to be created, several continuously arranged shape steels (when the steel type and size are the same) can be selected. Selection of section steel As with the selection of slot generation member, selection is done by using the mouse data button. When the selection is completed, when the mouse data button is clicked in the space where there is no member, the members to create the slot are completed. .

When the beam and the plate are selected, the slot is formed only when the bottom of the beam is attached to the bottom of the slot generating member according to the direction in which the slot is to be created.

When the member for which the slot is to be created and the section steel passing through the member are selected, a hole type is displayed on the screen according to the type of the section steel.

After entering the slot type and the dimensions according to the type and pressing the Cut Slot button below, a slot is created.

Cut Snip Creation Tool (223)

31 and 32 are screens of the cut snip generation tool 223 and execution result screens.

The cut snip generation tool 223 generates a snip in the shape of an H beam, a channel, and an angle.

The screen configuration of the cut snip generation tool 223 is, as shown in Figure 31, a steel beam (Steel Beem) combo box, image box, height (H) text box, width (W) text box, length (L) ) It includes a textbox, angle (A) textbox, [selection] button, [execute] button, and [exit] button. Here, the select type in the steel beam combo box is an H-beam, a channel, and an angle, and the H-beam and a channel. Is each one type, and the angle has three types.

First, the steel type for sniping is selected from the selection type. In this case, in the case of Angle, one of the types A, B, and C of the snip type item is selected.

Then, select the member. Select the member by left mouse click. Multiple selections are possible, and there is no limit to the number of selections.

The position of the member to be sniped determines the snip position based on the point at which the member is selected. A snip is generated at a portion close to the member selection position based on the length of the section steel and 1/2 of the depth value.

When selecting a member other than the section steel specified in the Select Type, an error message appears.

Then, enter each numerical value for sniping.

Here, H is a height value for cutting the steel, L is a length value for cutting the steel, W is a width / 2 value of the snip And A is an angle value for sniping.

Each time a member is selected, the Depth / 2 value of the selected member is entered as the H and L values, and W = 30 and A = 45 ° are the default values.

Finally, select the Run button to create the snip.

Hole Extrude Generation Tool (224)

33 and 34 are screens and execution result screens of the hole extrude generation tool 224.

The screen configuration of the hole extrude generation tool 224 includes a hole type combo box, a hole check box, a [SELECT] button, and a [HOLE generation] button as shown in FIG. 33.

In order to create a hole, the [Select] button is pressed, and then a plate or a shape steel on which the hole is to be selected is selected and completed. After selecting the part with the mouse data button, click once more anywhere in the view to complete the part selection.

The selection of the member to create the hole is completed, and the shape of the hole shape (HoleShape: Shape, ComplexShape, Ellipse, etc.) to be created is drawn or arranged. At this time, when arranging the hole shape (HoleShape), the hole shape (HoleShape) should be attached to the surface of the member in the direction in which the plate or section steel is placed.

Once the HoleShape has been placed, select the placed HoleShape. Once selected, click the Create Hole button to create a hole.

Hole Array Creation Tool (225)

35 to 37 are screens of the hole array generation tool 225 and execution result screens.

The screen configuration of the hole array (Hole Array) generation tool 225, as shown in Figure 35, the effective angle of the rectangle, the number of rows, the number of columns, row spacing, column spacing text box, hole check box and combo box, [SELECT] It contains a button.

In order to generate the hole, press the [Select] button, and then select and complete the plate or the steel where the hole is to be generated. After selecting the part with the mouse data button, click once more anywhere in the view to complete the part selection.

Selection of a member to generate a hole is completed, and a hole shape (HoleShape: Shape, ComplexShape, Ellipse, etc.) to be created is drawn or placed.

Enter the values for the HoleShape to create in the Array.

After entering the value, if you select HoleShape, the values of the number of rows, the number of columns, and the spacing of the rows are applied to show in advance where the hole will be created. If the location is not correct, press the mouse reset button, modify the value again, and select HoleShape. If the position of the hole is correct, click the mouse data button to generate the hole.

Drain Hole & Vent Hole Creation Tool (226)

38 and 39 are screens and an execution result screen of the drain hole & vent hole generation tool 226.

The drain hole and vent hole generation tool 226 may have a width (W) and a diameter (R) text box, an offset text box, and a multi hole as illustrated in FIG. 38. ) Count and Pitch text box, Hole checkbox and combo box, Rotate Angle text box, [Select] button and [Create] button.

First, press the [Select] button, and then select and select a member to create a hole. The selection is made with the mouse data button, and when the selection is completed, the mouse data button is clicked on the empty space of the view.

Once the member to create the hole is selected, the [Create] button is activated and inputs each numerical value of the hole. In this case, the value is the size of the hole, the offset is the distance away from the starting point, and the multi-hole is the number of holes and the distance between the holes, and the rotate. Is the rotation angle of the hole (Hole).

After that, press the [Create] button to create a hole and follow the mouse button. Once the position of the hole is determined, click the mouse data button to create the hole.

Outfit Hole Creation Tool (227)

40 and 41 are screens and execution result screens of a pipe hole of the outfit hole generation tool 227.

As shown in FIG. 40, the screen configuration of the fit hole generation tool 227 is a hole check box, a combo box, a pipe hole tab, and a cable hole tab. It includes a [Selet] button and a [Create] button. Here, the pipe hole tab includes an image box and a gap text box.

A method of generating a pipe hole using the fit hole generation tool 227 is as follows.

First, the pipe hole tab is selected, and then a gap between the pipe and the plate is input.

Thereafter, after pressing the [Select] button, a plate on which a hole is to be created is selected and selection is completed. At this time, the selection is selected by the mouse data button (mouse left button), and the selection is completed by clicking the mouse data button on the empty space of the view. Plate selection can be selected by clicking once, and deselecting by clicking once more to select a plurality of plates.

Then, the pipe passing through the plate is selected. When the selection is complete, pipe hole is created by clicking the empty data of the view with the mouse data button.

42 and 43 are screens and execution result screens of a cable hole of the outfit hole generation tool 227.

As shown in FIG. 42, an image hole, a cable hole type combo box, an A (width), a B (height) value text box, Contains the Rotate Angle textbox.

A method of generating a cable hole tab (Tab) using the fit hole generation tool 227 is as follows.

Press the [Select] button, select a plate on which a hole is to be created, and complete the selection. At this time, the selection is selected by the mouse data button (left mouse button), and when the selection is completed, the mouse data button is clicked on the empty space of the view. Plate selection can be selected by clicking once, and deselecting by clicking once more to select a plurality of plates.

After that, the hole size is input to the values A and B of the cable hole, and then the [Create] button is pressed to place the cable hole at the position where the cable hole is to be created.

Finally, when the position of the hole is determined, the cable hole is created when the mouse data button is clicked.

Standard Joint Creation Tool (228)

44 and 45 are screens and an execution result screen of the standard joint creation tool 228.

The standard joint generation tool 228 generates a cutback and a welding line, and a stiffener is generated and sniped according to the joint type.

If you set the default joint type, dimension value and weld information for the current construction in the joint default setting, only the joint type set in the standard joint list appears in the list. In this case, when all welding information for each welding line is not set in the joint default setting, the joint name is displayed in red in the standard joint list.

Welding Information Setting If there is a value set for the welding information in the Joint Default Setting when checking, the set value is displayed in the welding information window. If the welding information is not set in the joint default setting, the welding type and the joint code will not appear.

The operation method of the standard joint generation tool 228 is as follows.

First, select the desired joint type from the standard joint list and input the member information.

Here, the relevant attribute values are input before joining the member. Property values include Setting, Cope, Property, and Welding Information. Some types don't have Setting, Cope, or Property. The setting is a dimension input value for generating a stiffener and a snip, the cope is a dimension input value for generating a cop, and the property is a stiffener. ) Only the material value needed for creation can be selected, and the large and small size values of the magnetic material are inherited as they are. The steel grade is fixed in PL. Weld inputs welding information for each welding line of a joint type.

To create a welding line, after setting welding information, select [OK] to create a welding line. At this time, if there is a value set in the Joint Default SetUp in Setting and Weld, the set values are displayed.

Then, after inputting the member information, the parent member is selected.

The parent member selection is selected by left mouse click. After selecting the parent member, click the left mouse button on the empty space without any member to complete the parent member selection. You can select up to two parent members, and if more than two are selected, a warning message appears.

When the selection of the parent member is completed, the child member is selected.

The magnetic material selection is selected by clicking the left mouse button. If you continuously click on the child you want to select with the left mouse button, you can make multiple selections. If you execute the joint with the member selected as the parent member as the child member, a warning message appears.

When the parent member and the child member are selected, only types that can be jointed to the currently selected member appear in the list.

Finally, click the Run button to run the joint. At this time, if the user selects Run without setting the welding information, a message box indicating that the welding information is not set appears. Selecting the [Yes (Y)] button in the message box executes a joint without creating a welding line.

Another method of operation of the standard joint creation tool 228 is as follows.

First, select the parent member with the left mouse click.

After selecting the parent member, select the parent member by clicking the left mouse button on the empty space without member.

Next, select the child member by clicking the left mouse button. At this time, if you continuously click the child member to be selected with the left mouse button, multiple selection is possible, and there is no limit to the number of selections.

When the parent member and the child member are selected, only types that can be jointed to the currently selected member appear in the list. Here, the desired joint type is selected from the standard joint list.

Then, the absence information is input. At this time, related attribute values are inputted before joining the member.

Finally, click the Run button to run the joint.

On the other hand, in the general joint (Joint) type, the flange (Flange) of the top of the parent member and the flange (Flange) of the top of the magnetic member to face each other to be a joint (Joint). And, the joint is possible only when the magnetic member is located at the center of the width of the mother member. Only members with free steel grade "RB (Round Bar)" can be used. In addition, the magnetic member must be located at the center of the mother member width to allow the joint. Here, the parent member is a member having a wider width is the parent member.

Parent and child members must be attached to cut back. When cutback of the magnetic member penetrating the mother member, the shorter side of the mother member is deleted. If the member is a channel, CutBack will not be executed if the child member passes through the parent member.

Standard Joint Restoration Tool (229)

46 is a screen of a standard joint restoration tool 229.

The standard joint restoration tool 229 restores the jointed member to a state before the joint using a standard joint tool.

In the operation method, first, the number of parent members is selected.

At this time, if only one side of the magnetic member is a joint (Joint), the number of one parent member is selected. If there are joints on both sides of the magnetic member, select the number of two parent members. Joints are provided on both sides of the magnetic member, but if only one part of the mother member wants to restore the joint, select one parent member.

Next, click the [Select] button to make the parent member selectable.

Then, select the parent member.

Here, the selection of the parent member selects the parent member with a left mouse click. After selecting the parent member, deselect the parent member by clicking the left mouse button on the empty space without any member. At this time, a warning message appears when selecting more than the number of parent members selected.

Next, the magnetic member is selected.

Here, selecting the magnetic member selects the magnetic member by clicking the left mouse button. If you continuously click on the child you want to select with the left mouse button, multiple selection is possible, and there is no limit to the number of selections. When restoring a joint by selecting the member selected as the parent member as the child member, a warning message appears.

Finally, click the [Restore] button to execute the joint restoration.

Absence Information Tool (230)

47 is a screen of the member information tool 230.

The member information tool 230 is a tool that allows the user to check the member information (XData) created or modified.

The screen configuration of the member information tool 230 includes an XData item, an XData data, a bevel information, a hole information, an XData change button, and a member selection button as shown in FIG.

Here, the XData items are basically 24 kinds of XData items that the member has upon creation.

The XData data indicates the actual XData of the member selected by the user. At this time, the part which is not to be corrected by the user in yellow indicates that if the wrong information remains in the absence after the user incorrectly inputs the related information, confusion may occur, thus maintaining the original information.

The bevel information shows the bevel information to the user when the member selected by the user is the bevel.

The hole information shows the HOLE information of the member whose user created the HOLE.

The XData change button is used when a user wants to apply an XData value to a member after modification except for an unmodifiable part, and the member select button is used to select a member that the user wants to see XData. Press and select the part.

Operation of the absence information tool 230 is as follows.

First, click the member selection button and then click the member. The member information stored by the clicked member is displayed. Then, when the member is clicked after the member selection button is pressed, the bevel and hole information of the clicked member is displayed.

Weld Creation Tool (241)

48 and 49 are multi-weld creation and sheet-based welding preparation screens of the weld generation tool 241.

The welding creation tool 241 functions to generate a welding line between two adjacent members and to register welding properties to be managed in the welding. Functions of the weld generation tool 241 include single welding, multiple welding, sheet metal welding, block welding.

First, in the single welding, when the magnetic member and the parent member to generate a welding are selected, a guideline for generating a welding line is shown, and a welding line may be generated by selecting a line to be registered as an actual welding among the guidelines.

The operation method of the single welding is as follows.

First, click on the [Select] button. At this time, the [Select] button is clicked to make the member selectable.

Next, the welding magnetic member is selected. To select a welding member, click the left mouse button to select the welding member. Right-click to release the selected member.

Then, the welding parent member is selected. To select a welding parent member, select the welding parent member by left clicking. Right-click to release the selected member.

Next, enter the welding type and welding information. At this time, when the member is selected, the parent / child member ID appears. Unnecessary entries are deactivated depending on the welding type. The depth of improvement is automatically calculated based on the thickness.

Next, a welding guideline is generated. If the left mouse button is clicked after the child member and the parent member are selected, the welding guide line is created.

Next, select the welding line. Select a line to be designated as a welding line among welding guidelines. At this time, the selected line is indicated by a red dotted line.

Finally, the welding line is confirmed. Left click on the empty space to confirm the welding line.

In the multi-welding, when a plurality of magnetic members and one parent member are selected to generate a welding, a guide line for generating a welding line is shown, and a welding line may be generated by selecting a line to be registered as a real welding among the guidelines.

The operation method of the multi-weld is as follows.

First, click on the [Select] button. Click the [Select] button to make the member selectable.

Next, enter the welding type and welding information. At this time, when the member is selected, the parent / child member ID appears. Unnecessary entries are deactivated depending on the welding type. The depth of improvement is automatically calculated based on the thickness.

Then, the welding magnetic member is selected. Left click to select the welding member. There is no limit to the number of magnetic member selections. After selecting the member, click the left mouse button on the empty space without the member to select the parent member. If you click the right button of the mouse, the selection of magnetism will be canceled in the order of the last choice.

Next, the weld parent is selected and a guideline is generated. Left click on the parent member creates a weld guideline.

Next, select the welding line. Select a line to be designated as a welding line among welding guidelines. At this time, the selected line is indicated by a red dotted line.

Finally, the welding line is confirmed. Left click on the empty space to confirm the welding line.

In the plate-based welding, when a magnetic member is placed on a plurality of plates, when selecting a magnetic member and a plurality of parent members, a guideline for generating a welding line is displayed, and a line to be registered as actual welding is selected from the guideline. Can be generated.

The operation method of the plate-based welding is as follows.

First, click on the [Select] button. Click the [Select] button to make the member selectable.

Next, enter the welding type and welding information. At this time, when the member is selected, the parent / child member ID appears. Unnecessary entries are deactivated depending on the welding type. The depth of improvement is automatically calculated based on the thickness.

Then, the welding magnetic member is selected. Left click to select the welding member. Only one child can be selected. The selected magnet is not highlighted. Once selected, the member cannot be selected again. When the welding magnetic member is selected, it is automatically skipped to the plate member selection.

Then, the plate member is selected. The plate member selection may be performed by selecting a plate member with a left click of the mouse. Multiple selection is possible, and the selected plate member is not highlighted. However, if a snap is placed on the plate member to be selected before the mouse is clicked, the member is highlighted.

Next, a welding guideline is generated. Create a welding guideline by left-clicking on an empty space.

Next, select the welding line. Select a line to be designated as a welding line among welding guidelines. At this time, the selected line is indicated by a red dotted line.

Finally, the welding line is confirmed. Left click on the empty space to confirm the welding line.

The block welding is used for generating a welding line between blocks and welding lines of a loose member.

The operation method of the block welding is as follows.

First, click on the [Specify Area] button. Click the [Specify Area] button to make the area selectable.

Next, specify an area. Use the left mouse button and drag to specify the area for creating the weld line. Zoning is only possible in 'plan view'.

If the region is specified, it shows the element IDs of all the members in the region and shows a list of all weldable guidelines that can be created.

Next, select the welding guideline of the desired position.

Then, welding information is set. Click the weld details in the selected list to select the desired weld type and click Change. Click a category to select the one you want.

Then click [Create Weld] to select the weld line.

Next, select the welding line. Select a line to be designated as a welding line among welding guidelines. At this time, the selected line is indicated by a red dotted line.

Finally, the welding line is confirmed. Left click on the empty space to confirm the welding line.

Weld Modification Tool (242)

50 is a screen of the welding modification tool 242.

The welding modification tool 242 serves to modify the welding information of the generated welding line or to delete the welding line.

The welding modification (single) of the welding modification tool 242 functions to directly select a welding line to modify or delete welding information.

The operation method of the welding correction (single) of the welding correction tool 242 is as follows.

First, select a welding line. Left-click to select a weld line to modify.

Then, welding information is displayed. After selecting the welding line, click the left mouse button once more to display the welding modification window.

Then, the welding information is corrected. It is used to switch the magnetic member and the parent member in the butt welding. Modify the welding information to the value you want to change.

Finally, edit and delete weld information. Click the Edit Welding Information button to edit the welding information with the modified welding information. Clicking the Delete weld information button deletes the weld line. Deleting the welding information does not require the step of modifying the welding information.

The welding modification (list) of the welding modification tool 242 shows a list of welds attached to the magnetic member when the welding magnetic member is selected, and selects a welding from the list to modify or delete the corresponding welding information.

The operation method of the welding correction (list) of the welding correction tool 242 is as follows.

First, the welding magnetic member is selected. Use the left mouse button to select the welding member.

Then, welding information is displayed. Highlight On Highlights the corresponding weld line. After selecting the welder member, click the left mouse button once more to display the weld correction window. The parent member welded with the welding member and the welding number list are displayed.

Then, the welding information is corrected. Select the welding number and modify the welding information to the value you want to change.

Finally, the welding information is corrected and deleted. Click the Edit Welding Information button to edit the welding information with the modified welding information. Clicking the Delete weld information button deletes the weld line. Deleting the welding information does not require the step of modifying the welding information.

Weld Separation Tool (243)

51 is a screen of the welding separation tool 243.

The welding separation tool 243 serves to modify welding information of the generated welding line or to delete the welding line.

The welding separation (length) of the welding separation tool 243 serves to directly select the welding line and input the length to separate the welding line.

An operation method of welding separation (length) of the welding separation tool 243 is as follows.

First, select a welding line. Click the left mouse button to select the welding line to be separated. Selecting a welding line displays the length of the welding line.

Then enter the length to separate the welding line. At this time, highlights are displayed by the separation length. When the reverse toggle is selected, highlights are displayed by the separation length from the opposite side.

Finally, separate the welding line. Click the left mouse button to separate the welding line by the separation length.

Welding separation (multi) of the welding separation tool 243 serves to separate the welding line by selecting a separation reference line and multi-selecting a welding line that extends over the reference line.

First, create a separate baseline. Create a separation baseline to separate the welding line.

Then select the separation baseline. Left-click to select the split baseline.

Next, the welding line is selected. Click the left mouse button to select the welding line to be separated. There is no limit to the number of welding line selections.

Finally, separate the welding line. After the welding line is selected, click the left mouse button once more to separate the welding line.

When the welding separation (by Edge) of the welding separation tool 243 selects a plate for separation line extraction, a separation reference line is generated at an input distance, and serves to separate the welding line over the reference line.

The operation method of the welding separation (by Edge) of the welding separation tool 243 is as follows.

First, the plate for the separation line extraction is selected. Selecting a plate produces a yellow separation baseline. Selecting a plate face parallel to the weld line will not separate the weld line.

Then enter the distance from the selected plate face where the separation reference line will be located. The separation baseline is created a distance away from the selected plate face. Moving the mouse changes the direction of the separation baseline.

Finally, separate the welding line. Once the separation baseline is created, clicking the left mouse button will separate all the welding lines facing the separation baseline.

Weld-On Tools (244)

52A to 52C are exemplary views illustrating a method of using the welding tool 244.

The welding coupling tool 244 functions to select two welding lines which are in contact with each other and combine them into one welding line.

The operation method of the welding tool 244 is as follows.

First, select the first welding line to join. Left-click to select the first weld line to join.

Next, select the second welding line to join. Left-click to select the second weld line to join.

Finally, join the welding line. After selecting the welding line to join, click the left mouse button once more to join the welding line.

Weld Check Tool (245)

53 is a screen of the welding check tool 245.

The welding check tool 245 checks a place where a welding line does not exist in the member in contact with each other and a place where the welding line is separated from the magnetic member.

Where there are no welds, the entire member in the file is read and lists the parts that do not have a weld line in the contact with each other. The operation method is as follows.

First, run the program. When you run the program, it reads the entire part and lists the parts that do not have a weld line.

Next, select a member from the list to highlight the two members in the view.

Finally, press the [Create Weld] button to execute the weld creation function.

On the other hand, in the case of unnecessary welding, the entire welding line in the pile is read and the welding number, the magnetic member and the mother member are displayed in the list when the magnetic member or the parent member is not present or the welding line is separated from the magnetic member. The operation method is as follows.

First, run the program. When you run the program, it reads the entire weld line and lists unnecessary welds in the list.

Next, select a weld from the list to highlight the corresponding weld line in the view.

Finally, delete the weld element. Press the [Delete] button to delete the selected welded element.

Welding Information Tool (246)

54 is a screen of the welding information tool 246.

The welding information tool 246 shows the welding XData of the selected welding line in a list, and is used when the welding XData needs to be modified. The operation is as follows.

First, click on the [Select] button. Click the [Select] button to make the welding line selectable.

Next, select the welding line. Click the left mouse button and select the welding line to select. Right-click to release the selected welding line.

Then, after selecting the welding line, click the left mouse button once more to display the welding information of the selected welding line.

Next, double-click the welding information property field to make it editable and input the welding information to be modified.

Then, click the [Modify] button. The modified welding information is updated in the welding XData and welding information list of the selected welding line.

Block Management Tool (241)

55 is a screen of the block management tool 241.

The block management tool 241 can create and edit the type and description of the matching block, and checks the matching block code, block stage, upper block code, block code of the matching subordinate (medium, leading, forging, forging). You can add, delete, and edit information such as description.

The name of the design file must be the block code registered at the current construction, and the current working design file must be the check block. When this condition is met, the program configuration screen of the block management tool 241 appears.

The block code generation method of the block management tool 241 is as follows.

Select the upper block code of the block code to be created and click the Add button. This adds an empty blockcode line as the last child of the selection blockcode. Write the block code to add to the blank line and click the mouse anywhere other than the item being edited or press the keyboard arrow. A message box will pop up asking you to confirm the block code addition. Click OK to add the block code.

The block code deletion method of the block management tool 241 is as follows.

Select the block code you want to delete and click the Delete button. If the selected block code is a block code with block allocation (block code is red) or a block code with a lower block code, it is not deleted. Otherwise, it can be deleted.

The block information editing method of the block management tool 241 is as follows.

When the block management tool is executed, the grid containing block information is basically not editable. To edit the block information (block code, block stage, upper block, block description), check the edit check box in the upper right corner.

Then double-click the block code you want to edit. Then, the block code becomes editable. After typing the code to be changed, press enter, a change confirmation message box appears and click OK to change the block code.

Then click on the block stage to edit. A combo box is created on the stage of the clicked block, and if the upper block is the contrast, the counter block is the counter block, if the counter block is the counter block, if the counter block is the counter block, if the counter block is the counter block, the counter block is the counter block. Can be selected.

Then click on the higher blockcode to edit. A combo box appears in the upper block that you clicked.If the current block is a leading counterfeit according to the current block code, if the counterparts of the current control code are minor, the current code is PE, the current control, the middle, and the leading counter. You can select the upper code of the control, PE, current control, medium, preceding, and minor. When editing the upper block of the block code, the selected block code line moves to the lower node of the upper block code to be edited.

Finally, double-click the description of the block code to edit. It will be editable. Write down the description and press enter. A confirmation message box will appear. If you confirm, the block description will be created.

Block Assignment / Release Tool (252)

56 and 57 show screens of the block allocation / release tool 252.

The block allocation / release tool 252 may allocate and release a block in the absence of a design file corresponding to the selected block number. To conveniently allocate and free blocks in the design file, there are views such as Show Blocks Only, Show Blocks Only, and Show Blocks Highlighted.

The block allocation method of the block allocation / release tool 252 is as follows.

First, select the block code of the block to which the block is allocated. Assigned blocks (blockcode color blue or blocks with assignment letters in the assignment column) cannot be allocated.

Next, select the members of the block to be assigned a block code from the design file.

Finally, right-click on the selected block code and click on the Block Allocation pop-up menu, or click on the Assign to Block Allocation button. When a block is allocated in the actual design file, a message box shows how many blocks have been allocated, and the assigned block turns blue in text, and the assignment column shows the assignment column. Will be able to judge.

The block release method of the block allocation / release tool 252 is as follows.

Select the block code of the block to release the block. Since only the block to which the block is allocated can be released, only the block in which the block code is blue and the block allocation check part is marked as allocation can be released. Right-click on the block number and click Unblock on the pop-up menu or click the Unlock button on the block assignment to release the allocated block. When the block is released, the released block code turns red, and there is no assignment text in the allocation check part.

The block view function of the block allocation / release tool 252 is as follows.

The block view function is available in the popup menu that is displayed by left-clicking the block code only for the assigned block.

The Highlight Blocks View feature right-clicks the blockcode you want to highlight and clicks Select Highlights in the popup menu that appears.

The View Selected Blocks Only function displays only the members that correspond to the selected block code. If you click View Selected Only and click the view you want to see once, only the members of the selected block appear in the selected view.

The block exclusion view function is used to exclude only the block among the members currently displayed in the view.

The Show All feature lets you see all hidden parts while viewing only the selection blocks and the exclude selection blocks in the view. Click the Show All button at the bottom of the program screen.

Zone Creation Tool (253)

58 is a screen of the zone creation tool 253.

The zone creation tool 253 is a tool that can create, modify, and delete zone data.

An operation method of the zone generation tool 253 is as follows.

First, press the Create button to create new Zone data. Next, write down the zone name, color, and description and press the create button to complete the creation.

Next, to modify the zone data, select the zone data of the column to be modified and press the modify button. After entering the modifications in the modification window, press the edit button to apply the modifications.

Next, to delete the zone data, select the zone data of the column to be deleted and press the delete button to complete the deletion.

PBS Tree Tool (254)

59 is a screen of the PBS Tree tool 254.

The PBS Tree tool 254 displays the block structure of the currently working project and the member as a tree, and displays the welding number in the welding tree at the bottom when welding exists when selecting the group and the member. You can select a member in the tree to get its location and quantity, or you can select a weld to modify the weld properties.

The operation method of the PBS tree tool 254 is as follows.

First, select a block code or part number and right-click to display the pop-up menu.

[Select] button in the pop-up menu allows the members belonging to the selected block to be selected in the view. The [View] button displays only the elements belonging to the selected block in the view. After selecting, click the left mouse button on the view to apply. [Review View] button returns the view state by selecting or applying the view. [Quantity] button displays the quantity of the member, and [Re-display Tree] button reconstructs the tree by refreshing the current PBS tree.

Select the welding number and click the right mouse button to display the pop-up menu. Here, the [Select] button causes the selected welding element to be selected in the view. The [Modify] button opens a dialog where you can modify the properties of the selected weld element.

MTO Tools (261)

60 is a screen of the MTO tool 261.

The MTO tool 261 includes a block (control block code), a panel (medium block code), a class (member small work type), a rev (revision, blank), and a number (joint member without a member number) as shown in FIG. : Contrast / Medium / Preceding Forged-Large-Earth / Preceded Forged), Ser.No. ([Temporary] Part Number, Auto Assigned or Entered by Modeling), Category (Steel Grade), Thick (Plate Thickness), Width (Plate Width), Length (Plate Length), Q'ty (Number of Plates), Material (Material), Weight (Net Weight), Area (Plate Area), Filename (DXF) Filename, Remarks are included. In this case, the priority of the number in the contrast, the middle bath, and the preceding middle code field is preceded by the middle bath, the middle bath, and the contrast. In the order of smallest and leading smallest code fields, the order of priority is first. In other words, if there is a preceding minor and a minor, it means that the leading minor is entered.

In the screen, the font color is black, the plate is blue, the beam is a steel, and the red is a member (bending member) in which no DXF file (single view) is produced. View function can be divided into three views: all view, plate only view, and section view only.

If you press the Save as Excel button, a dialog box asking for the save path appears. Confirm the save path and press the Save button to save it to Excel. When the saving is completed, a message box will open and you can see the MTO Report saved as Excel by pressing OK.

Clicking the Extract DXF button brings up a dialog box asking for the path to save. If you specify the path and press OK, the single part file is created in the specified path.

Assembly Ordering Tool (271)

61 is a screen of the assembly order specifying tool 271.

The assembling order designation tool 271 gives a preliminary procedure for creating a DAP assembling flowchart and an assembling order of each block.

The operation method of the assembly order designation tool 271 is as follows.

First, select the block to which the assembly group will be assigned. Right-clicking on a blockcode item brings up a pop-up menu with the View function. If you click View Selection Only and click the screen of the view you want to see, only the members of the selection block code appear on the screen of the clicked view.

Then, click on the selection highlight to highlight the members of the current block. Clicking the View All or View All button at the bottom of the program will show the entire block. Select the blockcode, apply the Select Only view, and specify the assembly group. Check the assembly order of the assembly groups. The assembly order number is the assembly order of the current assembly group. Select the members to assign the assembly group.

If the currently displayed screen of the selected assembly group is different from the screen that should be shown in the assembly instruction diagram of the DAP, the form you want to show in the assembly instruction diagram using the X, Y, and Z values of the rotation angle items of the assembly group. Can be rotated. X, Y, Z of rotation angle means the axis to be rotated and the value of each item means rotation angle.

In order to rotate from the modeling screen to the screen that should be shown in the assembly instruction diagram, the modeling screen must be rotated 180 degrees on the X axis, so it can be displayed in the form shown in the assembly instruction diagram. Enter.

Then select the member, enter the rotation angle and click the Create button. An assembly group is added to the assembly group screen with the creation confirmation message.

Then, in order to check the assembly group you specified, right-click on the order of the assembly group and check the view function in the popup menu. In the assembling group checking process, the missing or incorrectly added members in the current assembly group can be added or subtracted by the member addition and exclusion functions of the pop-up menu. Click the missing part and then click Add part to include it in the current assembly group.

Next, create an assembly group and enter the rotation value in the direction to be shown in the assembly instructions. Double click the rotation angle item or press enter to edit the rotation angle. After entering the rotation angle, click the Save button. If the save button is not clicked, the entered rotation value is not saved.

The subgroup designation method in the assembly order designation tool 271 is as follows.

If an assembly group is designated, the subassembly group of the assembly group can also be designated. This is because a subgroup of the assembly group may be needed in the process of creating the assembly instructions. The subgroups 1 and 2 can be separated from the assembly instructions only when the subgroup items are enclosed in the assembly group.

Then, to specify a subgroup, click on the assembly group to which the subgroup is to be assigned, and apply only the selection view to display only the current assembly group on the screen. Then select the members to designate the subgroup, check the subgroup number to classify the subgroup, and click the Create button. At this time, to delete the added subgroup, click the subgroup number and press the delete button.

The loose group designation method in the assembly order designation tool 271 is as follows.

Click on the block containing the loose piece. Select a member to designate as a loose piece, select which block stage to designate as a loose member in the block combo box, and click the Apply button. When the loose piece is applied, a loose piece symbol and a corresponding member number are registered in the loose piece.

Block Tree Drawing Tool (272)

62 is a screen of the block tree diagram creation tool 272.

The screen structure of the block tree diagram creation tool 272 includes a name text box, a company number text box, a [create] button, and a [close] button as shown in FIG. Here, the present name and the company number are the name and the company number entered in the previous work.

When the [Create] button is pressed, a dialog box appears asking for the path where the block tree diagram will be stored. If the user designates a path and presses OK, the block tree diagram creation starts.

When the writing is completed, a completion message box appears. When you click OK, another message box is opened to open the created block tree diagram. If you press the [Yes] button, you can see the created block tree diagram.

Quantity summary table making tool (273)

63 is a screen of the quantity summary table creation tool 273.

The screen configuration of the quantity summary table creation tool 273 includes a name text box, a company number text box, a shape exclusion check box, a [create] button, and a [close] button as shown in FIG. Here, the present name and the company number are the name and the company number entered in the previous work. The shape exclusion check button indicates whether or not to include the shape of the block in the quantity summary table.

When the [Create] button is pressed, a dialog box appears asking for a path to store the summary table. If the user selects a path and clicks OK, the summary table is started. At this time, since it takes some time to prepare the summary of the quantity, the progress of the work can be known as the progress bar.

When the creation is complete, a completion message box will appear. If you click OK, another message box will be displayed to open the summary of the volume. If you press the [Yes] button, you can see the summary table.

Assembly point drawing tool (274)

64 is a screen of the assembly instruction diagram creation tool 274.

The screen structure of the assembly instruction drawing tool 274 includes a name text box, a company number text box, a [create] button, and a [close] button as shown in FIG. Here, the present name and the company number are the name and the company number entered in the previous work.

When the [Create] button is pressed, a dialog box appears asking for a path to store the assembly instruction diagram. Specifying a path and pressing OK starts creation of the assembly instruction diagram. At this time, the assembly instructions also take some time to write, so the progress of the work can be seen as the progress of the progress bar.

When the creation is complete, a completion message box appears, and when you click OK, another message box appears to immediately open the assembly instructions. If you press the [Yes] button, you can check the assembly instructions.

Anode Tool (281)

65 is a screen of an anode tool 281.

The anode tool 281 is a tool for modeling an anode in order to calculate a welding quantity of an accessory anode.

The screen configuration of the anode tool 281 is an anode material combo box, temporary part number text box, anode height text box, anode length text box, anode ( Anode) Width text box, Plate height text box, Plate length text box, Plate width text box, Anode creation direction combo box, Place button, Close button Doing. Here, the anode material combo box is set by ALUMINUM ALLOY as a default and brings a material registered in ProjectSetting. The anode generation direction may be basically generated in three directions of X, Y, and Z.

The operation method of the anode tool 281 is as follows.

First, input the dimension input (Anode, Plate height, length, width), and select the generation direction (X, Y, Z).

Then, after pressing the [Place] button, only one point is clicked. At this time, if only one point is clicked after input of the dimension and direction, an anode is created based on the direction at the point clicked by the user.

HandGrip Tool (282)

66 is a screen of a HandGrip tool 282.

The handgrip tool 282 is a tool for modeling a handgrip in order to calculate a welding quantity of an accessory handgrip.

As shown in FIG. 66, the screen configuration of the hand grip tool 282 is a hand grip steel combo box, a steel combo box, a hand grip material combo box, and a temporary member number text box. , HandGrip Height Textbox, HandGrip Length Textbox, HandGrip Angle Textbox, HandGrip Spacing Textbox, HandGrip Creation Direction Combobox, [Place] It includes a button and a [Close] button.

Basic steel grades of the HandGrip are SB and PI. The steel grade size shows steel grades of SB and PI registered in the current project.

The material of the hand grip is different from the anode and the default, and the rest is the same. Shows the material registered for each project in the ProjectSetting. The temporary member number is the same as the anode.

The handgrip angle (HandGrip Angle) is a Z-axis, so the basic direction of the hand grip (HandGrip) inputs the angle to rotate in the X, Y axis.

The handgrip (Grip) is generated in two and represents a position where one handgrip is separated.

The basic direction of creation of the HandGrip is the Z axis.

The operation method of the HandGrip tool 282 is as follows.

First, the steel grade and size of the hand grip are selected.

Next, the corresponding dimensions of the HandGrip are input.

Next, the angles of the X and Y axes of the hand grip are input.

Finally, after pressing the [Place] button, one point is clicked. At this time, after inputting dimensions and directions, only one point is clicked and a hand grip is generated based on the direction and angle at the point clicked by the user.

StdLug Tool (283)

67 is a screen of the StdLug tool 283.

The StdLug tool 283 is a tool for modeling the StdLug to calculate the welding quantity of the accessory StdLug.

The screen configuration of the StdLug tool 283 includes a StdLug type combo box, a type-specific type (STD_LUG) combo box, a temporary part number text box, a [Place] button, a [Close] button, and a StdLug image box. Doing.

There are five StdLug types (A: LIFT, TB, TC, TD, and TE: TURN OVER).

The type for each type STD_LUG represents each type included in the corresponding StdLug according to the StdLug type selected by the user. Each type represents TYPE-TONS. Each type is grouped in a GraphicGroup.

The operation method of the StdLug tool 283 is as follows.

First, select the StdLug type you want.

Next, the type of each type of StdLug type is selected.

Next, place the StdLug at the desired position after pressing the [Plate] button. At this time, the user can move the StdLug to the desired position.

Finally, place it in the desired location and click the mouse to confirm the creation of StdLug.

Handrail Tools (284)

68 is a screen of a handrail tool 284.

The handrail tool 284 is a tool for modeling a handrail in order to calculate a welding quantity of an accessory handrail.

The screen configuration of the handrail tool 284 is shown in Figure 68, General Tab, Detail Geometry Tab, Section Size Tab, Handrail It includes image box, [Place] button and [Close] button.

The General Tab includes a Post Height text box, a Post Spacing text box, a Midrail Number combo box, a Midrail Spacing text box, and a Handrail Full Length. It includes a text box, a PlaceBy combo box, a handrail variable image combo box, and a handrail image box.

The post interval indicates a placement interval between posts, and the number and interval of the midrails input each midrail arrangement interval according to the number of midrails selected by the user. can do.

In the PlaceBy combo box, the handrail is basically disposed as two points. In this case, the Two Point means a direction in which a handrail is generated.

The Detail Geometry Tab includes a Post Drop Down text box, a Kick Plate check box, a Handrail End Arc radius check box, and a Bottom Plate. It includes a thickness checkbox, bottom plate combo box, midrail isolation check box, and handrail variable image box.

When the kick plate is checked, a kick plate size is selected to generate a kick plate. When the kick plate is checked, a kick page is newly created in the section size page.

When the handrail end arc is checked, an arc shape is generated at both ends of the handrail.

The bottom plate check and thickness are checked when the user creates a plate at the end of the post for welding.

The midrail isolation checks when a midrail is to be separated and generates a midrail. By default, midrails are created with one member attached.

The section size tab includes a post tab, a top tab, a mid tab, and a section size image box.

The post tab includes a component steel grade combo box, a size combo box, a material combo box, a handrail component image box, and is a component steel grade, image, and material selection page.

The operation method of the handrail tool 284 is as follows.

First, input various dimensions related to the handrail. At this time, Post Height, Max. Spacing, Post Spacing, Midrail Number and Spacing, Handrail Overall Length must be entered.Post Drop Down, Kick Plate, Handrail End Arc Check and Radius, Bottom Plate Check and Thickness, Bottom Plate Material Midrail Isolation is optional.

Next, select the grade, size, and material of the Post, Mid, Top, and Kick (optional).

Finally, after pressing the [Place] button, click on two points to create a handrail in the direction of the two points.

Ladder Tool (285)

FIG. 69 is a screen of a MainLadder Tab of a ladder tool 285, FIG. 70 is a screen of an IntermediateTie Tab of a ladder tool 285, and FIG. Is a screen of the bolt tab of the ladder tool 285, FIG. 72 is a screen of the safe cage 1 tab of the ladder tool 285, and FIG. 73 is a ladder ) Screen of the SafeCage1 Tab of the tool 285.

The ladder tool 285 is a tool for modeling a handrail in order to calculate a welding quantity of an accessory handrail.

The screen configuration of the main ladder tab (MainLadder Tab) of the ladder tool (285) is a floor fastening combo box, a space (A) text box, a ladder width (C) text box, Ladder Height (D) Text Box, Ladder Spacing (B) Text Box, Intermediate Tie Check Box, Two Point Check Box, Stringer Steel Grade Combo Box, Stringer Size Size Combo box, Stringer combo box, Rung steel combo box, Rung Size combo box, Rung material combo box, SafeCage check box, Stringer Stringer Radius textbox, StringerPad width textbox, StringerPad thickness textbox, StringerPad length textbox, StringerPad material combobox, main ladder (MainLadder) Variable image box, [Plac e] button and [Close] button.

There are three types of floor fastenings for creating ladders.

In the case of the PAD type, a flat pad is formed at the bottom of the ladder. You can use StringerPad.

In the case of bolt fastening type, there are more UAs connected to the bottom by bolts. You can use BoltPage.

If the bottom is not fastened, nothing occurs on the bottom.

The distance from the wall refers to the distance from the wall when a ladder is generated and attached to the wall. The ladder width refers to the distance between the stringer and the stringer. The ladder height refers to the length of the entire ladder. The ladder spacing refers to the spacing between Rung and Rung.

When the check box for the use of the IntermediateTie is checked, an IntermediateTie Page may appear, and after inputting various variables, an IntermediateTie may be generated.

When the two points are checked, ladders corresponding to the height of the ladder are generated in the direction in which the two points are taken. If Two Point is not checked, Ladder is created as much as ladder height.

The Stringer steel grades are FB, UA and EA, and the steel grades of Rung are SB and PI. The size of each steel type shows the size of the project XML set in the ProjectSetting.

The material shows the contents of the project material set in the ProjectSetting. The shape of StringerPad varies depending on the steel type of StringerSize.

When checking whether the SafeCage is checked, a SafeCage is created in a ladder.

The Stringer Pad radius represents the corner radius of the Stringer Pad, the Stringer Pad thickness represents the thickness of the Stringer Pad, and the width of the Stringer Pad is The width of the StringerPad is shown, and the length of the StringerPad is the length of the StringerPad.

The screen configuration of the IntermediateTie Tab is shown in FIG. 70 as shown in FIG. 70. The distance text box from the bottom surface, the IntermediateTie interval text box, and the intermediate tie pad use check are performed. Box, IntermediateTie grade combo box, IntermediateTie combo box, IntermediateTie combo box, IntermediateTie Radius text box, InterTieTie Pad IntermediateTie Pad Thickness Text Box, IntermediateTie Pad Width Text Box, IntermediateTie Pad Length Text Box, IntermediateTie Pad It includes a material combo box and an IntermediateTie image box.

The distance A from the bottom surface represents the distance between the floor and the first intermediate tie, and the intermediate tie interval represents the interval between each intermediate tie.

The user can use the IntermediateTie by checking whether to use the IntermediateTie. If the user does not check the IntermediateTie, the IntermediateTie is generated according to the selected steel type.

The screen configuration of the bolt tab of the ladder tool 285 is a distance (A) text box from a clip bottom surface, a clip length (B) text box, as shown in FIG. , Distance from Stringer (C) text box, Clip steel combo box, Clip size combo box, Clip material combo box, Bolt radius (F) text box, Bolt (Bolt) Length (G) text box, Bolt bottom distance (H) text box, Bolt material combo box, Bolt variable image box.

The clip refers to a member attached to a stringer in a bolt fastening manner, and is connected to a stringer and a bolt.

The distance from the bottom of the clip is the distance from which the stringer falls off the floor as the clip is connected to the bolt, and the length of the clip indicates the total length of the clip. The distance from the stringer indicates the distance from which the clip is separated from the stringer.

The steel grade of the clip is set to UA by default, and the size or material generation format is the same as that of a stringer or an intermediate tie.

The bolt radius represents the radius of the bolt, the bolt length represents the total length of the bolt, and the distance from the bottom of the bolt is the bolt from the bottom surface. The bolt material is the same as Stringer and IntermediateTie.

Screen configuration of the SafeCage1 Tab of the Ladder tool 285 is shown in Figure 72, TopHoop passage width 1 (A) text box, TopHoop radius (B) Textbox, TopHoop Full width (C) Textbox, TopHoop steel combo box, TopHoop Size combo box, TopHoop combo box, VerticalHoop steel combo Combo box, VerticalHoop size combo box, VerticalHoop material combo box, SafeCage1 variable image box.

Screen configuration of the SafeCage2 Tab of the Ladder tool 285 is shown in Figure 73, IntermediateHoop & BottomHoop passage width 2 (A) text box, inter MediaHoop & BottomHoop Small Radius (B) Textbox, IntermediateHoop & BottomHoop Large Radius (C) Textbox, IntermediateHoop Grade Combo Box, IntermediateHoop Size combo box, IntermediateHoop material combo box, BottomHoop steel combo box, BottomHoop size combo box, BottomHoop material combo Box, SafeCage2 Contains a variable image box.

Stair Tool (286)

74 is a screen of a stair tool 286.

The stair tool 286 is a modeling tool for stair generation.

As shown in FIG. 74, the stair tool 286 is configured in a wizard form in which a form is completed and a [Next] button is pressed to proceed to the next step. Here, there are two types of stair types, Stair Type A and Stair Type B. Two Point is a mode to specify Work Point1 and Work Point2 by left mouse click or input. Input Height and Angle inputs Height and Angle value of stair and left click on Start Point to create stair or Take as input

The operation method of the stair tool 286 is as follows.

First, the desired stair type and stair mode are selected.

Then click the [Next] button to proceed to the next step.

In this case, in the two-point mode, the Work Point 1 is set by left-clicking the mouse or directly inputting the input fields of X, Y, and Z. Click [Next] button to set Work Point2. Set Work Point2 by clicking the left mouse button or inputting it directly in the input box of X, Y, Z.

Height, Angle In the input mode, enter the height and angle. Set the start point by clicking the left mouse button or inputting directly into the input boxes of X, Y and Z.

Next, click on the [Next] button to advance to Stair Dimensions. Enter the dimension values associated with the stair. Whenever the cursor is placed in the input box, the image related to the dimension is shown. Enter the Stair Width value. At this time, the stair width value should be entered between MAX 1200 and MIN 700.

Then enter the Nosing Distance value. At this time, the value of the stair nose distance (Nosing Distance) should enter a value of 30 or less.

Next, enter the thickness value of the tread. At this time, the thickness value of the tread should be entered below 40.

Next, enter the height value between the tread and the tread. At this time, the tread height should be entered between 180 and 230.

Next, enter the length of the upper stringer. At this time, the stringer is available only for the channel CHANNEL. Top Stringer Length must be a value of 100 or more. The bottom stringer length can be input only when the stair type is 'Stair Type B'.

Next, enter the length of the lower stringer. At this time, the bottom stringer length should be a value of 100 or more.

Next, click on the [Next] button to advance to 'Section Profiles'.

Next, select the profile for which you want to create a stringer.

Next, select a profile to create a handrail.

The stringer may select only 'CHANNEL' and the handrail may select only 'PIPE'.

Then, uncheck the [Create HandRail] checkbox to deactivate the control and do not create a handrail.

Next, click on the [Select] button in the Section Profiles frame. A window will appear where you can select a Profile.

The steel grade can be selected only 'CHANNEL' and 'PIPE'. If you select the wrong profile, a warning message appears.

Next, click on the [Next] button to advance to 'Select Landing'.

Here, when the stair type is Stair Type A, a length and a thickness value of a landing to be placed in the upper stringer are input. At this time, the length of the landing (Landing) is more than 100, the thickness should be more than 10. Deck plate thickness should be between 10 and 30. Unchecking Top Landing does not create Top Landing.

On the other hand, if the stair type (Stair Type) is Stair Type B, the length and thickness of the landing (Landing) to be placed in the upper stringer (Stringer) is input. Enter the length and thickness of the landing to be placed in the lower stringer. At this time, the length of the landing (Landing) is 100 or more, the thickness should be 10 or more. Unchecking Top Landing and Bottom Landing does not generate Landing.

Then click the [Next] button to advance to 'HandRail Options'.

Set the dimension values of the handrail created by the stair.

When the handrail generation check state is released from the section profile, the handrail option is not displayed. In the case of Stair Type A, the D2 value is deactivated.

When one Mid Handrail Count is selected, the H3 value is deactivated. Here, D1 is a distance from the top stringer generated at the top of the stair to the post handrail, and a value D1 is smaller than the top stringer length. Should be.

D2 is the distance from the bottom stringer generated under the stair to the post handrail. The value of D2 should be smaller than the Bottom Stringer Length.

H1, H2 and H3 are the heights between the handrails and should be at least 200.

H / R spacing is an interval between a handrail and a handrail, and H / R spacing may have a maximum value of 1500.

Finally, click the Place button to run the stair.

Check-in Tool (291)

75 is a screen of the check-in tool 291.

The check-in tool 291 has a function of reading and processing attribute information of members and welds belonging to a block file currently being worked on, and storing them in a database.

When executed from the menu, a confirmation window as shown in FIG. 75 appears.

If you press the [Yes] button on the confirmation window, the program is executed and all the property information is stored in the DB. Pressing the [No] button in the confirmation window cancels the save.

If you choose to save the property, the check-in is executed. If it is checked to run at the end, check-in is executed automatically at the end of MicroStation.

Project / Block Match Tool (292)

76 is a screen of the project / block matching tool 292.

The project / block matching tool 292 is used to match the project code of the member and the block code if the current construction project code and the block code are different. It is applied to all members at run time.

First, the project / block matching tool 292 is executed.

Then click the [Change] button to change the project code and block code of all the parts in the block. In this case, it should not be used when the block is allocated.

Regeneration Tool (293)

77 is a screen of the Regeneration tool 293.

The regeneration tool 293 sequentially reassigns temporary part numbers.

Click the [Execute] button of the Regeneration tool 293. Click the [Execute] button to display the original part number and the changed part number in the list.

Then change the temporary member number. Fig. 77 shows how the original part number and the changed part number appear in the list.

The regeneration tool 293 should not be used after drawing reference numbers.

Drawing Number Match Tool (294)

78 and 79 show screens of the reference numeral matching tool 294.

The drawing member number matching tool 294 matches drawing numbers and connection member numbers registered in SEBOM with each other in modeling, and updates necessary values in a database.

If you select a work type, drawing number and click 'search' button, information registered in SEBOM will appear in the list. Yellow in the list on the screen means that the modeling is matched, white means not matched.

If a list to be matched is selected in the SEBOM list, matchable member information appears in the modeling list.

If matchable member information does not appear in the modeling list, the modeling member information may be found by inputting a tolerance of width, length, and weight.

Material and large workpieces When the material and large species of SEBOM data and modeling data coincide with each other, they appear in the modeling list.

When unchecking, the material and large work are ignored. Checking all mismatched parts displays all mismatched part information in the modeling.

Double-click the modeling list screen to display the matching option window.

Checking each item of material, weight, and large work piece updates SEBOM's data with modeling data.

If you click the [Location] button, the member selected in the modeling list will blink and you can check the position of the member.

Click the [>] button to perform the matching. Matching simply updates the absent XData on the modeling. In order to update the actual DB, you must execute the DB CheckIn by clicking the [Apply] button.

Since yellow matches in the SEBOM list, select the part you want to unmatch in the yellow list.

If you select the list you want to unmatch, the modeling list shows the members on the model that are currently matched.

Click the [◁] button to cancel the match. Unmatching simply updates the absent XData in modeling. In order to update to the actual DB, you must execute the DB CheckIn by clicking the [Apply] button.

Click the [Apply] button to update the matching information in the database.

Welding Confirmation Tool (295)

80 and 81 show screens of the welding confirmation tool 295.

The welding confirmation tool 295 matches welding numbers and connecting member numbers registered in SEBOM with welding information on modeling and updates necessary values in welding XData.

If you select drawing number and click [Search] button, welding information in drawing number registered in SEBOM is displayed on the list. The welding confirmation is not shown in the list by default. To display the list of weld numbers confirmed, check all and click the [Browse] button.

The orange color on the screen indicates that the welding number has been confirmed, yellow means that there are no parts in the modeling, white means that the welding number has not been confirmed, and light blue indicates the welding number. This is the case when the welding line is created in. If you create the welding line and confirm the welding number, it turns orange.

The welding number can be confirmed only when the drawing part number match is made.

When welding number is created by creating a welding line in welding number confirmation, select the list to which welding number is to be confirmed from the list. Click 'Location' in the selected list to display the parts in the modeling. Right-click on the selected list to display the popup menu (Create Weld, View).

Next, click on the Create weld menu to create a weld line. Click the Create Weld menu to display the Create Weld window. Select the welding information and click on the 'Create' button. Draw the welding line directly on the part where the welding line will enter. When the weld line is created, the selected list changes to light blue.

Next, click the [Confirm] button to confirm the welding line. At this time, the list turns orange when it is confirmed.

On the other hand, when the welding number is confirmed using the already generated welding line, the member in which the welding line is generated is selected from the welding number confirmation list. When the welding line is created by using the welding tool, the member matching the two members in which the welding line is generated is selected from the welding number confirmation list. The position of the member can be confirmed using 'locate'.

Next, click the [Confirm] button to confirm the welding line. Click the [Confirm] button to confirm the welding number. When confirmed, the list turns orange. The welding property information of the welding line where the welding number is confirmed is updated with the connection member number, welding number, confirmation status, and minor number.

Then, the welding information after fixing the welding number is corrected. Select weld list to modify weld information. Right-click and click Modify Weld on the popup menu. Left click on the welding line to be modified and click again to bring up the welding modification tool. After modifying the welding information, click 'Modify' to update the welding information.

Finally, click the [Confirm] button to confirm the welding number.

When welding number is confirmed in welding number confirmation, only XData in modeling is changed, and DB CheckIn must be executed to update to the actual database.

Table 1 below shows a comparative analysis of the offshore structure design and integration system of the present invention and systems of other companies for each related product.

As described above, the method of designing and integrating the offshore structure of the present invention and the recording medium storing the computer program for the method include reports on initial project management, 3D CAD modeling, drawing generation, and overall requirements. ), The technical problem of the present invention can be solved by solving one CAD.

It will be apparent to those skilled in the art that various modifications and changes can be made in the present invention without departing from the spirit or scope of the present invention as defined by the appended claims. It will be appreciated that such modifications and variations are intended to fall within the scope of the following claims.

1 to 2 is a block diagram of the offshore structure design and integration program according to a preferred embodiment of the present invention,

1 is a functional diagram of the function of the project and the block setting program,

2A to 2C are functional diagrams of the marine structure design and integration program.

3 is a project menu screen in the main screen of the project and block setting program 100

4 is a screen of a Default menu in the main screen

5 and 6 are execution screen of the Joint (Joint) setting menu in the main screen

7 is a setting list screen for each type in the joint setting menu;

8 is a welding line setting screen in the joint setting menu

9 and 10 are MTO and Weight & COG execution screen of the Report menu on the main screen.

11 shows a screen of the profile generation tool 211.

12 shows a screen of the plate creation tool 212.

13 shows a screen of a user input tab of the built-up generating tool 213.

14 shows a screen of the member welding tab Tab of the built-up generating tool 213.

15 is a screen of an Excel input tab of the built-up generating tool 213.

FIG. 16 is a diagram illustrating the generated built-up image.

17 shows a screen of the Cone & Pipe Creation Tool 214.

18 shows a screen of the seam generation tool 215.

19 shows a screen of the PipeSeam creation tool 216.

20 shows a screen of the Profile Change / Restore Tool 217.

21 and 22 are screens of the fillet generation tool 218 and execution result screens.

23 and 24 show screens of the scallop generation tool 219 and execution result screens.

25 and 26 show screens of the chamfer generating tool 220 and execution result screens.

27 and 28 are screens of the bevel generation tool 221 and execution result screens.

29 and 30 are screens of the slot generation tool 222 and execution result screens.

31 and 32 are screens of the cut snip generation tool 223 and execution result screens.

33 and 34 are screens and execution result screens of the hole extrude generation tool 224.

35 to 37 are screens of the hole array generation tool 225 and execution result screens.

38 and 39 are screens of the drain hole & vent hole generation tool 226 and the execution result screen.

40 and 41 are screens and execution result screens of a pipe hole of the outfit hole generation tool 227.

42 and 43 are screens and execution result screens of a cable hole of an outfit hole generation tool 227.

44 and 45 show screens and execution results of the standard joint creation tool 228.

46 shows a screen of standard joint restoration tool 229.

47 is a screen of the absence information tool 230.

48 and 49 are a multi-welding and sheet metal welding creation screen of the weld generation tool 241

50 shows a screen of a weld modification tool 242.

51 shows a screen of the weld separation tool 243.

52A to 52C are exemplary views showing a method of using the welding tool 244.

53 shows a screen of the welding check tool 245.

54 shows a screen of the welding information tool 246.

55 shows a screen of the block management tool 241.

56 and 57 show screens of the block allocation / release tool 252.

58 shows a screen of the zone creation tool 253.

59 shows a screen of the PBS Tree tool 254.

60 shows a screen of the MTO tool 261.

61 is a screen of the assembly order specifying tool 271.

62 shows a block tree diagram creation tool 272 screen.

63 is a screen of the quantity summary table creation tool 273.

64 is a screen of the assembly point diagram creation tool 274.

65 shows a screen of an anode tool 281.

66 shows a screen of HandGrip tool 282.

67 shows a screen of StdLug tool 283.

68 shows a screen of the handrail tool 284.

69 shows the screen of the Main Ladder Tab of the Ladder Tool 285. FIG.

70 shows the screen of the IntermediateTie Tab of the Ladder tool 285.

71 shows the Bolt Tab screen of the Ladder Tool 285.

72 shows a screen of a SafeCage1 Tab of the Ladder Tool 285.

73 shows a screen of SafeCage1 Tab of the Ladder Tool 285. FIG.

74 shows a screen of a stair tool 286.

75 shows a screen of the check-in tool 291.

76 shows a screen of the project / block matching tool 292.

77 shows a screen of the Regeneration tool 293.

78 and 79 show screens of reference numeral matching tool 294.

80 and 81 show screens of the welding confirmation tool 295.

[Description of Code for Major Parts of Drawing]

100: project and block setting program 110: project

111: Construction Opening Tool 112: Construction Registration Tool

113: Construction Delete Tool

114: construction setting completion tool

115: Block code generation tool

116: master block code reload tool

117: Exit tool 120: Default section

121: Material setting tool 122: Bevel setting tool

123: steel management tool 130: joint portion

131: joint setting tool 140: the report part

141: MTO tool 142: Weight & COG tool

200: offshore structure design and integration program 210: member generating unit

211: Profile Creation Tool 212: Plate Creation Tool

213: Built-up generation tool

214: Cone & Pipe Creation Tool 215: Seam Creation Tool

216: PipeSeam generation tool

217: Profile change / restore tool 218: File creation tool

219 Scallop generation tool 220 Chamfer generation tool

221: Bevel generation tool 222: Slot generation tool

223: Cut Snip Creation Tool

224: Hole Extrude Generation Tool

225: Hole Array Creation Tool

226: Drain Hole & Vent Hole Creation Tool

227: Outfit Hole Creation Tool

228 standard joint creation tool

229: Standard Joint Restoration Tool 230: Part Information Tool

240: welding function 241: welding creation tool

242: welding modification tool 243: welding separation tool

244 weld welding tool 245 weld check tool

246: welding information tool 250: block management unit

251: block code management tool 252: block allocation / release tool

253 Zone Creation Tool 254 PBS Tree Tool

260: Report function unit 261: MTO tool

270: DAP part 271: assembly order designation tool

272: Block Tree Diagram Creation Tool 273: Quantity Summary Table Creation Tool

274: Assembly instruction drawing tool 280: Accessory part

281: Anode Tool 282: HandGrip Tool

283 StdLug Tool 284 Handrail Tool

285 Ladder Tool 286 Stair Tool

290: other functions 291: check-in tool

292: Project / Block Matching Tool 293: Regeneration Tool

294: Drawing Number Match Tool 295: Welding Confirmation Tool

Claims (12)

In the marine structure design and integration method, (a) installing and running an offshore structure design and integration program on the PC; (b) Through the offshore structure design and integration program, set basic data for each construction and block-related data calculation, select materials used in each construction, set default materials for construction, and use them in each project. Adding a basic joint type, setting dimension information and welding information for each added joint type, and storing and managing the set construction file in Excel; And (c) through the offshore structure design and integration program, create the shaped steel member, plate member, built-up member, seam and weld line in the member, and create the member Create fillets, scallops, chamfers, and bevels at edges of slots, and slots, snips, holes, and joints in the members. Joint), generating the absence information; Offshore structure design and integration method which provides from one project to 3D CAD modeling, drawing generation, and report on total requirements through one program. The method of claim 1, wherein the offshore structure design and integration program is: A construction opening tool for opening a construction to be set by inputting or selecting a construction number; A construction registration tool for registering a construction by entering or selecting a construction number; A construction deletion tool for inputting or selecting a construction number to be deleted and entering a password to delete the construction; A construction setting completion tool for setting the open construction; A block code generation tool for importing an Excel file that creates block codes to be added and storing them in a DB; A master block code reload tool for updating newly added or deleted block code in a master block code to a block code table of the project and block setting program; And An exit tool for terminating a program; Offshore structure design and integration method comprising a. The method of claim 1, wherein the offshore structure design and integration program is: A material setting tool for displaying a registered and unregistered situation as a construction material of an open construction in color, changing a default material, adding a construction material, and deleting a registered construction material; A bevel setting tool for inputting bevel data required for each construction; And A section management tool for registering and deleting section steel required for each construction, generating and registering an XML file, and modifying the registered XML file; Offshore structure design and integration method comprising a. The method of claim 1, wherein the offshore structure design and integration program is: If the joint is selected for the first time in the current project or if the joint type is not registered, the empty list is displayed. If the joint type is registered in the current project, the registered joint type is displayed in the list. And a joint setting tool that sets the type of dimension and welding information, adds, registers, and deletes a joint type. The method of claim 1, wherein the offshore structure design and integration program is: An MTO tool that displays the MTO of the check block when the check block code is selected while the construction file is open, and designates a directory and a file name when an Excel save button is input, and outputs it to Excel; And If the construction file is open and selected for each item to be viewed, the weight & COG report for each item is displayed and if the save button is entered, the weight & COG is output to Excel after specifying the directory and file name. Tools; Offshore structure design and integration method comprising a. The method of claim 1, wherein the offshore structure design and integration program is: A profile generation tool for receiving an item including a steel grade, a material, a steel grade size, a large diameter, and a small diameter from a user and generating a steel member for modeling; A plate generation tool for receiving an item including a steel grade, a material, a steel grade size, a large diameter, and a small diameter from a user and generating a plate member for modeling; A built-up generating tool for generating a built-up member that cannot be created with a steel or plate member and storing it as an Excel file; A cone & pipe generation tool for generating cones and pipes that are built-up members that cannot be created by members; A seam generation tool for generating seams and weld lines in the member; A pipe seam generating tool for generating a seam in a forming direction in a pipe of a section steel; A profile change / restore tool for changing the steel grade, material, and size of an existing profile and restoring the changed profile to an initial state; A fillet generating tool for generating an edge portion of the member into a fillet; A Scallop generation tool for generating an edge portion of the member as a scallop; A Chamfer generation tool for generating an edge portion of the member as a chamfer; A bevel generation tool for beveling an edge portion of the member; A slot generation tool for generating slots in the member; A cut snip generation tool for generating snips in the shape of an H beam, a channel, and an angle of the member; A hole extrude tool for creating a hole in the member; A hole array generation tool for generating holes of various shapes including rectangular and circular in the member; A drain hole and a vent hole generation tool for generating a drain hole and a vent hole in the member; An Outfit Hole generation tool for creating a pipe hole and a cable hole in the member; A standard joint generation tool for generating cutbacks and welding lines of the parent member and the child member; A standard joint restoration tool for restoring the jointed member to the state before the joint using a standard joint tool; And Offshore structure design and integration method comprising a; member information tool that allows the user to check the member information created or modified. The method of claim 1, wherein the offshore structure design and integration program is: A weld creation tool for creating a weld line between two adjacent members and registering weld attributes to be managed in the weld; A welding modification tool for modifying welding information of the generated welding line or deleting the welding line; A welding separation tool for correcting welding information of the generated welding line or deleting the welding line; A welding joining tool for selecting two welding lines which are in contact with each other and joining them into one welding line; A welding check tool for checking a place where a welding line does not exist in the members in contact with each other and a place where the welding line is separated from the magnetic member; And And a welding information tool for displaying the welding data of the selected welding line in a list and correcting the welding data. The method of claim 1, wherein the offshore structure design and integration program is: A block code management tool for creating and editing a type and description of a matching block, and adding, deleting, and editing information such as a matching block code, a block stage, an upper block code, and a block code description under the matching; A block allocating / releasing tool for allocating and releasing blocks in the absence of a design file corresponding to the selected block number; Zone creation tool for creating, modifying, and deleting zone data; And A PBS tree tool that displays the block structure of the project currently being worked on and the members belonging to the tree, and the welding number in the welding tree at the bottom if the welding is present when selecting the parts and members. Offshore Structure Design and Integration Methods. The method of claim 1, wherein the offshore structure design and integration program is: An assembling procedure designation tool for assigning an assembling procedure for each block, a preliminary procedure for creating a DAT assembly flowchart; A block tree diagram creation tool for creating a block tree diagram; A quantity summary table creation tool for creating a quantity summary table; And An assembly structure diagram creation tool for creating an assembly structure diagram; Offshore structure design and integration method comprising a. The method of claim 1, wherein the offshore structure design and integration program is: An anode tool for modeling the anode to calculate the welding quantity of the accessory anode; A HandGrip tool for modeling a handgrip to calculate a weld quantity of an accessory HandGrip; A StdLug tool for modeling StdLug to calculate the welding quantity of the accessory StdLug; A handrail tool for modeling the handrail to calculate the welding quantity of the accessory handrail; Ladder tool for modeling the ladder to calculate the welding amount of the accessory Ladder (Ladder); And Stair (Stair) tool for modeling the stair (Stair); Offshore structure design and integration method comprising a. The method of claim 1, wherein the offshore structure design and integration program is: A check-in tool for reading and processing attribute information of members and welds belonging to the block file currently being worked on and storing them in a database; A project / block matching tool for matching the project code of the member and the block code if the current construction project code and the block code are different; A regeneration tool for sequentially reassigning temporary part numbers; A drawing number matching tool for matching registered drawing numbers and connecting member numbers with each other in modeling and updating necessary values in a database; And And a welding confirmation tool for matching the registered welding number and connecting member number with the welding information on the model and updating necessary values in the welding data. A recording medium storing a computer program for the marine structure design and integration method according to any one of claims 1 to 11.

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