CN110674623A - Reading system and method for modeled embedded part positioning information - Google Patents
Reading system and method for modeled embedded part positioning information Download PDFInfo
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- CN110674623A CN110674623A CN201910909682.0A CN201910909682A CN110674623A CN 110674623 A CN110674623 A CN 110674623A CN 201910909682 A CN201910909682 A CN 201910909682A CN 110674623 A CN110674623 A CN 110674623A
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- 239000007943 implant Substances 0.000 claims 3
- 238000013461 design Methods 0.000 abstract description 37
- 230000007547 defect Effects 0.000 abstract description 4
- 238000009435 building construction Methods 0.000 description 28
- 238000010586 diagram Methods 0.000 description 6
- 238000010295 mobile communication Methods 0.000 description 6
- 238000010276 construction Methods 0.000 description 4
- 229910000831 Steel Inorganic materials 0.000 description 3
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- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04B—GENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
- E04B1/00—Constructions in general; Structures which are not restricted either to walls, e.g. partitions, or floors or ceilings or roofs
- E04B1/38—Connections for building structures in general
- E04B1/41—Connecting devices specially adapted for embedding in concrete or masonry
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- H04—ELECTRIC COMMUNICATION TECHNIQUE
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Abstract
A reading system and method of the modeling embedded part positioning information, including a processing terminal; the processing terminal comprises an automatic input module, and the automatic input module is used for automatically inputting the positioning information of the embedded part or the positioning information of the sleeve into the processing terminal. The processing terminal also comprises arrangement software and an import and export module; the arrangement software is used for arranging each embedded part or each sleeve in the sorted second table in a preset position of the opened interface and generating a detailed table; the lead-in and lead-out module is used for leading out a table III with a set format; for importing the adjusted table five back into the detail table. The defect of low efficiency that the positioning information of the embedded parts or the positioning information of the sleeve pipes are manually input into a computer one by one when the positioning information table of the embedded parts or the positioning information table of the sleeve pipes given in a design drawing is checked in the prior art is effectively overcome.
Description
Technical Field
The invention relates to the technical field of embedded part positioning and modeling, in particular to a reading system and a reading method of modeled embedded part positioning information, and particularly relates to a reading system and a reading method of embedded part positioning information based on BIM.
Background
An embedded part, also called an embedded part, is a member which is provided with steel plates and anchoring ribs in a structure and is used for connecting structural members or fixing non-structural members. For example, the connecting piece for fixing the post-process (such as door, window, curtain wall, water pipe, gas pipe, etc.). There are many points where the concrete structure is connected to the steel structure.
A pre-buried pipe, also called a casing, is a channel in which a pipe (usually a steel pipe, a cast iron pipe or a PVC pipe) is left in a structure for passing through the pipe or leaving a hole for equipment service. Such as those used for passing various pipelines (such as strong and weak electricity, water supply, gas, etc.) at a later stage. It is commonly used for the pipe preformed hole on the concrete wall beam.
In addition, with the vigorous development of the building industry, the building construction site gradually develops towards standardization, industrialization and scientification, and more innovation achievements and technical applications are applied. In the conventional arrangement of embedded parts or sleeves, in order to check the positioning information table of the embedded parts or the positioning information table of the sleeves given in a design drawing such as an electronic building construction drawing (the positioning information table of the embedded parts or the positioning information table of the sleeves respectively contain the positioning information of the embedded parts or the positioning information of the sleeves), the positioning information of the embedded parts or the positioning information of the sleeves respectively contained in the positioning information table of the embedded parts or the positioning information table of the sleeves is firstly manually input into a computer one by one in a Revit of BIM software, then the embedded parts or the sleeves are arranged in BIM software according to the input corresponding positioning information and then displayed, therefore, the positioning information of the embedded part in the positioning information table or the positioning information of the sleeve in the positioning information table can be visually checked through the displayed position of the embedded part or the position of the sleeve.
However, it is inefficient to manually input the embedded part positioning information or the casing positioning information, which is respectively contained in the embedded part positioning information table or the casing positioning information table, into the computer one by one in the Revit of the BIM software. How to improve the input speed of the positioning information of the embedded part and the positioning information of the sleeve is an urgent problem to be solved.
Disclosure of Invention
In order to solve the problems, the invention provides a reading system and a reading method of modeled embedded part positioning information, which effectively overcome the defect of low efficiency that the positioning information of embedded parts or the positioning information of sleeves is manually input into a computer one by one when a positioning information table of embedded parts or a positioning information table of sleeves given in a design drawing is checked in the prior art.
In order to overcome the defects in the prior art, the invention provides a reading system of modeled embedded part positioning information and a solution of the method thereof, which specifically comprise the following steps:
a reading system of modeled embedded part positioning information comprises a processing terminal;
the processing terminal comprises an automatic input module, and the automatic input module is used for automatically inputting the positioning information of the embedded part or the positioning information of the sleeve into the processing terminal.
The processing terminal also comprises arrangement software and an import and export module;
the arrangement software is used for arranging each embedded part or each sleeve in the sorted second table in a preset position of the opened interface and generating a detailed table;
the lead-in and lead-out module is used for leading out a table III with a set format; for importing the adjusted table five back into the detail table.
The method for the reading system of the modeled embedded part positioning information comprises the following steps:
the positioning information of the embedded part or the positioning information of the sleeve is automatically input into the processing terminal.
The method for automatically inputting the positioning information of the embedded part or the positioning information of the sleeve into the processing terminal comprises the following steps:
step 1-1: copying a positioning information table of the embedded part or a positioning information table of the sleeve into the processing terminal;
step 1-2: and respectively identifying the positioning information of the embedded part or the positioning information of the sleeve copied into the positioning information table of the embedded part or the positioning information table of the sleeve in the processing terminal through a character identification and conversion tool, and converting the information into a table I with a set format.
After the positioning information of the embedded part or the positioning information of the sleeve is automatically input into the processing terminal, the method further comprises the following steps:
and sorting the table I with the set format according to the categories to obtain a sorted table II.
After the sorted table two is obtained, the following method is further included:
according to the number of the embedded parts or the number of the sleeves in the sorted table II, arranging each embedded part or each sleeve in the sorted table II in a preset position of an interface opened by the arrangement software, generating a detail list, and then leading out a table III in a set format through a lead-in and lead-out module by the generated detail list, wherein the table III in the set format comprises a column representing a transverse coordinate value x of each embedded part or each sleeve in the preset position, a column representing a longitudinal coordinate value y of each embedded part or each sleeve in the preset position, a column representing a central point elevation z of each embedded part or each sleeve in the preset position and a column representing a sleeve type or an embedded part type.
After the table three in the set format is derived, the method further comprises the following steps:
in the table III with the set format, sorting is carried out according to categories to obtain a sorted table IV, then the sorted table II is opened, and the row which represents the sleeve number or the embedded part number in the sorted table II, the row which represents the transverse coordinate value x of the sleeve or the transverse coordinate value x of the embedded part in the sorted table II, the row which represents the longitudinal coordinate value y of the sleeve or the longitudinal coordinate value y of the embedded part in the sorted table II and the row which represents the central point elevation of the sleeve or the central point elevation of the embedded part in the sorted table II are respectively replaced by the row which represents the sleeve number or the embedded part number in the sorted table IV, the row which represents the transverse coordinate value x of each embedded part or each sleeve in a preset position in the sorted table IV, the row which represents the longitudinal coordinate value y of each embedded part or each sleeve in the preset position in the sorted table IV and the row which represents the longitudinal coordinate value y of each embedded part or each sleeve in the preset position in the sorted table IV are respectively copied and pasted in a copying and pasting mode A column in the sorted table four representing the centre point elevation z of said each insert or each casing in a predetermined position, thereby converting the sorted table four into the adjusted table five.
And guiding the adjusted table five back into the detail list through the guiding-in and guiding-out module, and then automatically changing each embedded part or each sleeve arranged in the position preset by the previously opened interface to the position according to the position information of the embedded part or the sleeve in the detail list, thereby realizing automatic arrangement.
The invention has the beneficial effects that:
the reading system and the reading method of the modeled embedded part positioning information comprise a D2D pair (consisting of a D2D transmitting terminal and a D2D receiving terminal) and the mobile communication terminal of the mobile communication user, wherein the D2D transmitting terminal multiplexes the uplink of the mobile communication terminal of the mobile communication user to transmit information for the D2D receiving terminal. It is considered that a malicious monitor will collect the received signal power by using the power radiometer, and determine whether the information is transmitted between the pair D2D based on the collected signal power. While information is transmitted between the D2D transmitting terminal and the D2D receiving terminal, the mobile communication terminal of the mobile communication user transmits an interference signal with transmission power uniformly distributed at intervals, which affects the detection of a malicious monitor. The reading system and the reading method of the modeled embedded part positioning information have the advantages of low complexity, simple operation and easy realization. Compared with the existing scheme for realizing covert communication by using channel uncertainty, the method has better performance and universality. The defect that a covert communication mechanism in the safe transmission of D2D content sharing in the prior art is established on the basis that a malicious monitor is uncertain about a monitoring channel of the malicious monitor and has no universality is effectively overcome.
Drawings
FIG. 1 is a block diagram of a processing terminal of the present invention;
FIG. 2 is a flow chart of a method of the modeled embedded part location information reading system of the present invention;
FIG. 3 is a schematic diagram of an interface for copying a positioning information table of an embedded part into the processing terminal and opening the positioning information table by cajviewer software according to the present invention;
FIG. 4 is a schematic interface diagram of the first form converted into the set format according to the present invention;
FIG. 5 is a schematic view of an interface for each embedded part in a second sorted list according to the present invention;
FIG. 6 is an interface schematic of a generated schedule of the present invention;
FIG. 7 is a schematic of an interface for the placement software of the present invention;
FIG. 8 is a schematic interface diagram of a third table with a set format according to the present invention;
FIG. 9 is a schematic interface diagram of a fourth sorted table after pasting according to the present invention;
FIG. 10 is a schematic interface diagram of the adjusted table five being imported back to the detail table by the import/export module according to the present invention;
FIG. 11 is a schematic view of the interface after the final automatic placement of the present invention.
Detailed Description
The invention will be further described with reference to the following figures and examples.
As shown in fig. 1-11, the reading system of the modeled embedded part positioning information comprises a processing terminal; the processing terminal can be a computer, a laptop, a PDA or an intelligent wireless handheld terminal like a smartphone. The processing terminal comprises an automatic input module, and the automatic input module is used for automatically inputting the positioning information of the embedded parts or the positioning information of the sleeve pipes respectively contained in a positioning information table of the embedded parts or a positioning information table of the sleeve pipes in a design drawing such as an electronic building construction drawing into the processing terminal. The embedded parts are embedded parts, the sleeve pipes are embedded pipes, the positioning information table of the embedded parts or the positioning information table of the sleeve pipes in a design drawing such as an electronic building construction drawing respectively comprises the positioning information of the embedded parts or the positioning information of the sleeve pipes, the positioning information of the embedded parts comprises serial numbers, the serial numbers of the embedded parts, the types of the embedded parts, the transverse coordinate values x of the embedded parts, the longitudinal coordinate values y of the embedded parts and the central point elevation of the embedded parts, the central point elevation is the central elevation of the embedded parts, the serial numbers are the serial numbers of the embedded parts in the positioning information table of the embedded parts, the serial numbers can be gradually increased from a positive integer 1 to represent the serial numbers of the embedded parts, the embedded part numbers are unique identifiers preset for the embedded parts, the serial numbers of the embedded parts can be set to a character string format of 8BWX1502 VB1502 PT plus the serial number of the embedded parts, therefore, the embedded part can be marked, the type of the embedded part can be the type of the embedded part, for example, the type of the embedded part is as follows: P300-L225, taking the type of the embedded part as the type of the embedded part, wherein a transverse coordinate value x of the embedded part is a transverse coordinate value on the embedded position of the embedded part, and a longitudinal coordinate value y of the embedded part is a longitudinal coordinate value on the embedded position of the embedded part; the positioning information of the casing comprises a serial number, a casing type, a transverse coordinate value x of the casing, a longitudinal coordinate value y of the casing and a central point elevation of the casing, wherein the central point elevation is the central elevation of the casing, the serial number is a serial number of the casing in a positioning information table of the casing, the serial number can gradually increase from a positive integer 1 to represent the serial number of each casing, the casing number is a unique identifier preset for the casing, the casing number can be set to a character string format of 8BWX2503VBPT + the serial number of the casing, so that the casing can be identified, and the casing type can be the casing type, for example, the casing type is: DN50, using it as the type of the sleeve, the transverse coordinate value x of the sleeve is the transverse coordinate value on the embedded position of the sleeve, and the longitudinal coordinate value y of the sleeve is the longitudinal coordinate value on the embedded position of the sleeve. Thus, the method of automatically inputting the positioning information of the embedded part or the positioning information of the sleeve respectively contained in the positioning information table of the embedded part or the positioning information table of the sleeve in the design drawing such as an electronic building construction drawing can improve the automatic processing speed, and avoid the problem of low efficiency of manually inputting the positioning information of the embedded part or the positioning information of the sleeve into a computer one by one when the positioning information table of the embedded part or the positioning information table of the sleeve given in the design drawing is checked in the prior art. The processing terminal also comprises arrangement software and an import and export module; the arrangement software is used for arranging each embedded part or each sleeve in the sorted second table in a preset position of the opened interface and generating a detailed table; the import and export module is used for exporting a table III with a set format; for importing the adjusted table five back into the detail table. The placement software can be revit software in BIM software. The Import Export module can be an Import/Export Excel plug-in of revit software.
A method of modeling a system for reading embedded part location information, comprising:
the positioning information of the embedded parts or the positioning information of the sleeve pipes respectively contained in the positioning information table of the embedded parts or the positioning information table of the sleeve pipes in the design drawing such as an electronic building construction drawing are automatically input into the processing terminal. The embedded parts are embedded parts, the sleeve pipes are embedded pipes, the positioning information table of the embedded parts or the positioning information table of the sleeve pipes in a design drawing such as an electronic building construction drawing respectively comprises the positioning information of the embedded parts or the positioning information of the sleeve pipes, the positioning information of the embedded parts comprises serial numbers, the serial numbers of the embedded parts, the types of the embedded parts, the transverse coordinate values x of the embedded parts, the longitudinal coordinate values y of the embedded parts and the central point elevation of the embedded parts, the central point elevation is the central elevation of the embedded parts, the serial numbers are the serial numbers of the embedded parts in the positioning information table of the embedded parts, the serial numbers can be gradually increased from a positive integer 1 to represent the serial numbers of the embedded parts, the embedded part numbers are unique identifiers preset for the embedded parts, the serial numbers of the embedded parts can be set to a character string format of 8BWX1502 VB1502 PT plus the serial number of the embedded parts, therefore, the embedded part can be marked, the type of the embedded part can be the type of the embedded part, for example, the type of the embedded part is as follows: P300-L225, taking the type of the embedded part as the type of the embedded part, wherein a transverse coordinate value x of the embedded part is a transverse coordinate value on the embedded position of the embedded part, and a longitudinal coordinate value y of the embedded part is a longitudinal coordinate value on the embedded position of the embedded part; the positioning information of the casing comprises a serial number, a casing type, a transverse coordinate value x of the casing, a longitudinal coordinate value y of the casing and a central point elevation of the casing, wherein the central point elevation is the central elevation of the casing, the serial number is a serial number of the casing in a positioning information table of the casing, the serial number can gradually increase from a positive integer 1 to represent the serial number of each casing, the casing number is a unique identifier preset for the casing, the casing number can be set to a character string format of 8BWX2503VBPT + the serial number of the casing, so that the casing can be identified, and the casing type can be the casing type, for example, the casing type is: DN50, using it as the type of the sleeve, the transverse coordinate value x of the sleeve is the transverse coordinate value on the embedded position of the sleeve, and the longitudinal coordinate value y of the sleeve is the longitudinal coordinate value on the embedded position of the sleeve. Thus, the method of automatically inputting the positioning information of the embedded part or the positioning information of the sleeve respectively contained in the positioning information table of the embedded part or the positioning information table of the sleeve in the design drawing such as an electronic building construction drawing can improve the automatic processing speed, and avoid the problem of low efficiency of manually inputting the positioning information of the embedded part or the positioning information of the sleeve into a computer one by one when the positioning information table of the embedded part or the positioning information table of the sleeve given in the design drawing is checked in the prior art.
A method for automatically inputting the positioning information of embedded parts or the positioning information of sleeves respectively contained in a positioning information table of embedded parts or a positioning information table of sleeves in a design drawing such as an electronic building construction drawing into a processing terminal, comprising the steps of:
step 1-1: the staff of the construction unit copies the positioning information table of the embedded part or the positioning information table of the sleeve in the design drawing such as an electronic building construction drawing into a processing terminal; such copying may be that the worker of the construction unit puts the location information table of the embedded parts or the location information table of the sleeve in the design drawing such as the electronic building construction drawing from another storage terminal storing the location information table of the embedded parts or the location information table of the sleeve in the design drawing such as the electronic building construction drawing through a usb disk, and the storage terminal can be a computer, a notebook computer, a PDA or an intelligent wireless handheld terminal such as a smart phone. Copying a positioning information table of an embedded part or a positioning information table of a sleeve in a design drawing such as an electronic building construction drawing from a storage terminal, and copying the positioning information table of the embedded part or the positioning information table of the sleeve in the design drawing such as the electronic building construction drawing into a processing terminal; such copying may be performed by connecting a storage terminal storing a positioning information table of an embedded part or a positioning information table of a sleeve in a design drawing such as an electronic building construction drawing to a processing terminal via a network, and then transmitting the positioning information table of the embedded part or the positioning information table of the sleeve in the design drawing such as the electronic building construction drawing to the processing terminal via the communication connection, wherein the storage terminal may be a computer, a notebook computer, a PDA, or an intelligent wireless handheld terminal such as a smart phone.
Step 1-2: the method comprises the steps of respectively identifying the positioning information of the embedded part or the positioning information of the sleeve in a positioning information table of the embedded part or a positioning information table of the sleeve copied into a design drawing such as an electronic building construction drawing in a processing terminal through a character identification and conversion tool, and converting the information into a form I with a set format. Here, the method of identifying the positioning information of the embedded part or the positioning information of the sleeve in the positioning information table of the embedded part or the positioning information table of the sleeve copied to the design drawing such as the electronic building construction drawing in the processing terminal by the character recognition and conversion tool and converting the information into the table one with the set format may be: if the location information table of the embedded parts or the location information table of the casing in the design drawing such as the electronic building construction drawing copied to the processing terminal is in the caj file format, the character recognition and conversion tool is the caj converter, thus opening the caj converter, selecting the caj to pdf toolbar on the interface of the opened caj converter, adding the location information table of the embedded parts or the location information table of the casing in the design drawing such as the electronic building construction drawing in the processing terminal in the caj converter with the caj file format, then clicking the "start conversion" button to convert, obtaining the file in the pdf format corresponding to the location information table of the embedded parts or the location information table of the casing in the design drawing after conversion, storing the converted file in the pdf format corresponding to the location information table of the embedded parts or the location information table of the casing in the design drawing on the desktop of the processing terminal or in other set folders, selecting a pdf to excel function on the opened interface of the caj converter, and converting a file in a pdf format, which is converted to correspond to a positioning information table of an embedded part in a design drawing or a positioning information table of a casing, into a first excel file, wherein the first excel file is a first table in a set format; if the positioning information table of the embedded part or the positioning information table of the sleeve in the design drawing such as the electronic building construction drawing copied to the processing terminal is a file with a pdf format, a caj converter serving as a character recognition and conversion tool is opened, a pdf to excel function on an interface of the opened caj converter is selected, the positioning information table of the embedded part or the positioning information table of the sleeve in the design drawing of the file with the pdf format is directly converted into a first excel file, and the first excel file is a first form with a set format; if the embedded positioning information table or the bushing positioning information table in the design drawing, such as an electronic building construction drawing, copied into the processing terminal is a pdf-formatted file, so that cajviewer software serving as a character recognition and conversion tool is opened, firstly converting the embedded positioning information table or the bushing positioning information table in the design drawing of the pdf-formatted file into a word document, and then opening excel software in the processing terminal to convert the word document into an excel file I, wherein the excel file I is a set-format table I; thus, the positioning information table of the embedded part or the positioning information table of the sleeve in the design drawing such as an electronic building construction drawing is copied to a processing terminal by the staff of a construction unit; then the positioning information of the embedded part or the positioning information of the sleeve in the positioning information table of the embedded part or the positioning information table of the sleeve copied to the design drawing such as an electronic building construction drawing in the processing terminal is respectively identified by a character identification and conversion tool, and converted into a form with a set format, thereby realizing the method for automatically inputting the positioning information of the embedded parts or the positioning information of the sleeve respectively contained in the positioning information table of the embedded parts or the positioning information table of the sleeve in a design drawing such as an electronic building construction drawing into a processing terminal, the process of automatic identification and automatic construction improves the automatic processing speed, avoids the problems that when the positioning information table of the embedded part or the positioning information table of the sleeve given in the design drawing is checked in the prior art, the positioning information of the embedded parts or the positioning information of the sleeve pipes are manually input into a computer one by one, so that the efficiency is low. The excel file I comprises a table I, wherein the table I comprises a plurality of columns, and the columns are respectively a column for representing the serial number of each sleeve or embedded part, a column for representing the serial number of the sleeve or the embedded part, a column for representing the type of the sleeve or the type of the embedded part, a column for representing a transverse coordinate value x of the sleeve or a transverse coordinate value x of the embedded part, a column for representing a longitudinal coordinate value y of the sleeve or a longitudinal coordinate value y of the embedded part, and a column for representing the elevation of the central point of the sleeve or the elevation of the central point of the embedded part.
The method further comprises the following steps after the positioning information of the embedded parts or the positioning information of the sleeve pipes respectively contained in the positioning information table of the embedded parts or the positioning information table of the sleeve pipes in the design drawing such as an electronic building construction drawing is automatically input into a processing terminal:
in the table I with the set format, sorting is performed according to the categories to obtain a sorted table II. Specifically, in the first table with a set format, the sorting method according to categories may be: and in the table I with the set format, sequencing according to the type of the embedded part or the type of the casing pipe to obtain a sequenced table II.
After the sorted table two is obtained, the following method is further included:
according to the number of embedded parts or the number of sleeves in the sorted second table, arranging each embedded part or each sleeve in the sorted second table in a preset position of an interface opened by the arrangement software, generating a detail table, then leading the generated detail table out of a third table with a set format through a leading-in and leading-out module, wherein the third table with the set format can be led back into the detail table through the leading-in and leading-out module, and the third table with the set format comprises a column representing a transverse coordinate value x of each embedded part or each sleeve in the preset position, a column representing a longitudinal coordinate value y of each embedded part or each sleeve in the preset position, a column representing a central point elevation z of each embedded part or each sleeve in the preset position and a column representing a sleeve type or an embedded part type. The arrangement software can be revit software in BIM software, the preset position can be the same position or different positions for each embedded part or each casing, and thus, in the preset position of the arrangement software, the method for arranging each embedded part or each casing in the sorted table II comprises the following steps: in an interface opened by the revit software, selecting a model corresponding to each embedded part or each sleeve pipe in the sorted table II according to the type of the embedded part or each sleeve pipe, arranging the model on a preset position of the corresponding embedded part or sleeve pipe in a mouse dragging mode, generating a detail table by using an Import/Export Excel plug-in of the revit software, using the Import/Export Excel plug-in of the revit software as an Import and Export module, and exporting a table III with a set format by using the Import and Export module, wherein the table III with the set format can be imported back into the detail table by using the Import and Export module, and the table III with the set format comprises a column representing the number of the sleeve pipe or the embedded part, a column representing the transverse coordinate value x of each embedded part or each sleeve pipe in the preset position, and a column, The column representing the longitudinal coordinate value y of each embedded part or each casing in the preset position, the column representing the center point elevation z of each embedded part or each casing in the preset position and the column representing the casing type or the embedded part type, wherein the value of the column representing the casing number or the embedded part number in the table III with the set format is null.
After the table three in the set format is derived, the following method is also included:
in a table III with a set format, sorting according to categories to obtain a sorted table IV, then opening the sorted table II, and replacing the column representing the sleeve numbers or the embedded parts numbers in the sorted table II, the column representing the transverse coordinate values x of the sleeves or the transverse coordinate values x of the embedded parts in the sorted table II, the column representing the longitudinal coordinate values y of the sleeves or the longitudinal coordinate values y of the embedded parts in the sorted table II, and the column representing the central point elevation of the sleeves or the central point elevation of the embedded parts in the sorted table II in a copying and pasting manner respectively for the column representing the sleeve numbers or the embedded parts numbers in the sorted table IV, the column representing the transverse coordinate values x of each embedded part or each sleeve in a preset position in the sorted table IV, the column representing the longitudinal coordinate values y of each embedded part or each sleeve in a preset position in the sorted table IV and the column representing the longitudinal coordinate values y of each embedded part or each sleeve in a preset position in the sorted table IV A column representing the centre point elevation z of each insert or each casing in a predetermined position, thereby converting the sorted table four into the adjusted table five. Specifically, in table three with a set format, the sorting method by category may be: and in the table III with the set format, sequencing according to the type of the embedded part or the type of the casing pipe to obtain a sequenced table IV. The method comprises the steps of obtaining a sorted table four by the same method as the method for obtaining the sorted table two, obtaining the sorted table four by the same method as the method for obtaining the sorted table two, enabling the sorted table four and the sorted table two to have a mapping relation which is in one-to-one correspondence and is sorted according to the embedded part type or the sleeve pipe type, and replacing the row which represents the sleeve pipe number or the embedded part number in the sorted table four, the row which represents the sleeve pipe number or the embedded part number in the sorted table two, the row which represents the longitudinal coordinate value y of the sleeve pipe or the longitudinal coordinate value y of the embedded part in the sorted table two, and the row which represents the central point elevation of the sleeve pipe or the central point elevation of the embedded part in the sorted table two in a copying and pasting mode, the row which represents the sleeve pipe number or the embedded part number in the sorted table four, the row which represents each embedded part or the transverse coordinate value x of each sleeve pipe in a preset position in the sorted table four, and the row which represents the embedded part or the transverse coordinate value x, The column representing the longitudinal coordinate value y of each embedded part or each sleeve in the preset position in the sorted table four and the column representing the central point elevation z of each embedded part or each sleeve in the preset position in the sorted table four convert the sorted table four into the adjusted table five, so that under the one-to-one mapping relationship, the batch replacement mode of copying and pasting ensures that the data in the replaced column in the adjusted table five can faithfully and accurately reflect the positioning information of the embedded parts or the positioning information of the sleeves in the positioning information table of the embedded parts or the positioning information table of the sleeves in the design drawing such as an electronic building construction drawing, and the accuracy can be ensured on the premise of ensuring the improvement of the speed.
The adjusted table five is then imported into a detail list through an import and export module, namely, a column representing the number of the casing or the embedded part in the adjusted table five, a column representing a transverse coordinate value x of each embedded part or each casing in a preset position in the adjusted table five, a column representing a longitudinal coordinate value y of each embedded part or each casing in a preset position in the adjusted table five and a column representing a central point elevation z of each embedded part or each casing in a preset position in the adjusted table five replace the column representing the number of the casing or the embedded part in the detail list, the column representing a transverse coordinate value x of each embedded part or each casing in a preset position in the detail list, the column representing a longitudinal coordinate value y of each embedded part or each casing in a preset position in the detail list and the column representing a central point elevation z of each embedded part or each casing in a preset position in the detail list respectively, the column in the detail table representing the transverse coordinate value x of each embedded part or each sleeve in the preset position, the column in the detail table representing the longitudinal coordinate value y of each embedded part or each sleeve in the preset position and the column in the detail table representing the central point elevation z of each embedded part or each sleeve in the preset position form the position information of the embedded part or the sleeve; the detail list can automatically identify and change the adjusted form five, and then each embedded part or each sleeve arranged in the position preset by the interface opened previously can be automatically changed to the position according to the position information of the embedded part or the sleeve in the detail list, so that automatic arrangement is realized, an engineer can visually check the positioning information in the positioning information table of the embedded part or the positioning information table of the sleeve given in a design drawing such as an electronic building construction drawing according to each embedded part or each sleeve automatically arranged on the interface, and can detect whether mutual collision occurs on the position between the embedded parts or the sleeves. Such an automatic arrangement is efficient and intuitive.
The present invention has been described in an illustrative manner by the embodiments, and it should be understood by those skilled in the art that the present disclosure is not limited to the embodiments described above, but is capable of various changes, modifications and substitutions without departing from the scope of the present invention.
Claims (8)
1. A reading system of modeled embedded part positioning information comprises a processing terminal;
the processing terminal is characterized by comprising an automatic input module, wherein the automatic input module is used for automatically inputting the positioning information of the embedded part or the positioning information of the sleeve into the processing terminal.
2. The system for reading modeled embedded part positioning information according to claim 1, wherein the processing terminal further comprises a placement software and an import-export module;
the arrangement software is used for arranging each embedded part or each sleeve in the sorted second table in a preset position of the opened interface and generating a detailed table;
the lead-in and lead-out module is used for leading out a table III with a set format; for importing the adjusted table five back into the detail table.
3. A method of modeling a system for reading embedded part location information, comprising:
the positioning information of the embedded part or the positioning information of the sleeve is automatically input into the processing terminal.
4. A method of modeling a system for reading of insert positioning information according to claim 3, characterized in that the method of automatically entering the positioning information of the insert or the positioning information of the sleeve into the processing terminal comprises the steps of:
step 1-1: copying a positioning information table of the embedded part or a positioning information table of the sleeve into the processing terminal;
step 1-2: and respectively identifying the positioning information of the embedded part or the positioning information of the sleeve copied into the positioning information table of the embedded part or the positioning information table of the sleeve in the processing terminal through a character identification and conversion tool, and converting the information into a table I with a set format.
5. The method of modeling a system for reading of insert positioning information according to claim 4, further comprising the following method after the automatic input of the insert positioning information or the sleeve positioning information into the processing terminal:
and sorting the table I with the set format according to the categories to obtain a sorted table II.
6. The method for modeling a system for reading positioning information of an embedded part according to claim 5, further comprising the following steps after obtaining the second sorted table:
according to the number of the embedded parts or the number of the sleeves in the sorted table II, arranging each embedded part or each sleeve in the sorted table II in a preset position of an interface opened by the arrangement software, generating a detail list, and then leading out a table III in a set format through a lead-in and lead-out module by the generated detail list, wherein the table III in the set format comprises a column representing a transverse coordinate value x of each embedded part or each sleeve in the preset position, a column representing a longitudinal coordinate value y of each embedded part or each sleeve in the preset position, a column representing a central point elevation z of each embedded part or each sleeve in the preset position and a column representing a sleeve type or an embedded part type.
7. The method for modeling a system for reading placement information according to claim 6, further comprising the following method after said deriving table three in a set format:
in the table III with the set format, sorting is carried out according to categories to obtain a sorted table IV, then the sorted table II is opened, and the row which represents the sleeve number or the embedded part number in the sorted table II, the row which represents the transverse coordinate value x of the sleeve or the transverse coordinate value x of the embedded part in the sorted table II, the row which represents the longitudinal coordinate value y of the sleeve or the longitudinal coordinate value y of the embedded part in the sorted table II and the row which represents the central point elevation of the sleeve or the central point elevation of the embedded part in the sorted table II are respectively replaced by the row which represents the sleeve number or the embedded part number in the sorted table IV, the row which represents the transverse coordinate value x of each embedded part or each sleeve in a preset position in the sorted table IV, the row which represents the longitudinal coordinate value y of each embedded part or each sleeve in the preset position in the sorted table IV and the row which represents the longitudinal coordinate value y of each embedded part or each sleeve in the preset position in the sorted table IV are respectively copied and pasted in a copying and pasting mode A column in the sorted table four representing the centre point elevation z of said each insert or each casing in a predetermined position, thereby converting the sorted table four into the adjusted table five.
8. A method of modeling a system for reading out implant positioning information according to claim 6, characterized in that the adjusted table is imported back into the schedule again by the import export module, and then each implant or each casing arranged in a position preset in the previously opened interface is automatically changed to that position according to the position information of the implant or the casing in the schedule, respectively, thereby achieving automatic arrangement.
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Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN113609544A (en) * | 2021-03-26 | 2021-11-05 | 中铁十一局集团电务工程有限公司 | Hole reservation method and system based on BIM technology |
| CN115329450A (en) * | 2022-10-14 | 2022-11-11 | 三一筑工科技股份有限公司 | Embedded part copying method and device |
Citations (6)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US20130073268A1 (en) * | 2011-09-20 | 2013-03-21 | Bp Corporation North America Inc. | Automated generation of local grid refinement at hydraulic fractures for simulation of tight gas reservoirs |
| CN103678784A (en) * | 2013-11-27 | 2014-03-26 | 上海国际航运服务中心开发有限公司 | Device and method for generating three-dimensional images of embedded parts for irrigation structures |
| CN106295019A (en) * | 2016-08-15 | 2017-01-04 | 上海宝冶集团有限公司 | Heating ventilation air-conditioning system installation method based on BIM |
| CN109147013A (en) * | 2018-09-30 | 2019-01-04 | 深圳市华阳国际工程设计股份有限公司 | A kind of in-depth figure automatic generation method, equipment and the storage medium of component |
| CN109344506A (en) * | 2018-09-30 | 2019-02-15 | 深圳市华阳国际建筑产业化有限公司 | In-depth figure automatic generation method, equipment and the storage medium of BIM threedimensional model |
| CN109670192A (en) * | 2017-10-13 | 2019-04-23 | 上海宝冶建设工业炉工程技术有限公司 | A kind of component ID batch extracting method based on BIM |
-
2019
- 2019-09-25 CN CN201910909682.0A patent/CN110674623B/en active Active
Patent Citations (6)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US20130073268A1 (en) * | 2011-09-20 | 2013-03-21 | Bp Corporation North America Inc. | Automated generation of local grid refinement at hydraulic fractures for simulation of tight gas reservoirs |
| CN103678784A (en) * | 2013-11-27 | 2014-03-26 | 上海国际航运服务中心开发有限公司 | Device and method for generating three-dimensional images of embedded parts for irrigation structures |
| CN106295019A (en) * | 2016-08-15 | 2017-01-04 | 上海宝冶集团有限公司 | Heating ventilation air-conditioning system installation method based on BIM |
| CN109670192A (en) * | 2017-10-13 | 2019-04-23 | 上海宝冶建设工业炉工程技术有限公司 | A kind of component ID batch extracting method based on BIM |
| CN109147013A (en) * | 2018-09-30 | 2019-01-04 | 深圳市华阳国际工程设计股份有限公司 | A kind of in-depth figure automatic generation method, equipment and the storage medium of component |
| CN109344506A (en) * | 2018-09-30 | 2019-02-15 | 深圳市华阳国际建筑产业化有限公司 | In-depth figure automatic generation method, equipment and the storage medium of BIM threedimensional model |
Non-Patent Citations (2)
| Title |
|---|
| 徐亚男等: "ArchiCAD在污水处理厂施工图三维设计中的应用实践", 《中国给水排水》 * |
| 那称等: "铝合金模板施工中水电管线安装的预留预埋工艺改进", 《建筑施工》 * |
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN113609544A (en) * | 2021-03-26 | 2021-11-05 | 中铁十一局集团电务工程有限公司 | Hole reservation method and system based on BIM technology |
| CN115329450A (en) * | 2022-10-14 | 2022-11-11 | 三一筑工科技股份有限公司 | Embedded part copying method and device |
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|---|---|
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