CN111753364B - Construction method for constructing energy-saving building by adopting prefabrication method - Google Patents
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- 238000010276 construction Methods 0.000 title claims abstract description 30
- 238000009417 prefabrication Methods 0.000 title claims abstract description 30
- 238000000034 method Methods 0.000 title claims abstract description 19
- 238000009435 building construction Methods 0.000 claims abstract description 17
- 239000002689 soil Substances 0.000 claims description 3
- 230000009286 beneficial effect Effects 0.000 abstract description 3
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Abstract
The invention discloses a construction method for constructing an energy-saving building by adopting a prefabrication method, which comprises the following steps of: step S1: establishing a database, and importing past design drawings into the database; step S2: carrying out recognition analysis on the past design drawing to obtain the design characteristic information of the past design drawing; step S3: establishing a corresponding retrieval label for the design drawing according to the design characteristic information of the past design drawing so as to be used for searching; step S4: establishing a search engine for the design drawing according to the search label in the step S3; step S5: and the designer acquires the topographic information and the architectural style information of the land to be designed and analyzes the labels of the information. The design of the invention improves the design conception for the designer after the existing data resources are arranged, and can also provide conception reference for the designer in the special-shaped complex structure part, thereby effectively improving the design efficiency, reducing the design error rate and being beneficial to reasonable and efficient complete building construction work.
Description
Technical Field
The invention relates to the technical field of building construction, in particular to a construction method for energy-saving building construction by adopting a prefabrication method.
Background
The construction has the characteristics of long period, poor construction environment, high technical difficulty and the like, particularly in areas with long winter, connection between spring and autumn, synchronous rain and heat, strong solar radiation, long illumination time, large temperature difference, short frost-free period and dry and windy weather, so that the average annual air temperature of similar areas is below 10 ℃, the extremely highest air temperature can reach 37.9 ℃, the extremely lowest air temperature can reach-40.4 ℃, and the areas belong to cold areas according to construction climate subareas, for example, chinese patent with the authority of CN105040981A discloses a construction method for constructing an energy-saving building by adopting a prefabrication method, a building design unit designs a drawing of a building to be constructed, divides the whole building into a plurality of building modules according to a stress principle when the drawing is designed, and then sends the design of the building modules to a prefabrication unit for prefabricating the building modules, wherein the prefabrication unit comprises the following steps: (1) Setting a prefabricated field in an open-land environment, and building a prefabricated house capable of adjusting internal environment parameters; (2) Setting up a pedestal for prefabricating building modules in a prefabrication room; (3) Constructing a prefabricated template corresponding to the single building module on the pedestal by using steel according to the drawing standard of the single building module; (4) concrete casting is carried out on the built prefabricated templates; (5) The building module is solidified, and mainly solves the problem that the construction difficulty of building construction is high in cold weather.
However, the existing prefabricated building design and construction process is relatively long in design time, conventional design schemes are not convenient to reasonably utilize, conventional component parts in design conception buildings are provided for current designers, distribution design concepts are not convenient to provide for special-shaped complex components in the buildings, and design time and construction period are prolonged, so that a construction method for energy-saving building construction by adopting a prefabrication method is provided for solving the problems.
Disclosure of Invention
Based on the technical problems in the background technology, the invention provides a construction method for constructing an energy-saving building by adopting a prefabrication method.
The invention provides a construction method for constructing an energy-saving building by adopting a prefabrication method, which comprises the following steps of:
step S1: establishing a database, and importing past design drawings into the database;
step S2: carrying out recognition analysis on the past design drawing in the step S1 to obtain design characteristic information of the past design drawing;
step S3: establishing a corresponding retrieval label for the design drawing according to the design characteristic information of the past design drawing in the step S2 for searching;
step S4: establishing a search engine for the design drawing according to the search label in the step S3;
step S5: a designer obtains the topographic information and the architectural style information of the land to be designed, and analyzes the labels of the information;
step S6: inputting the topographic information of the land to be designed and the label to which the building style belongs in the step S5 into the search engine in the step S4 for searching;
step S7: the search engine carries out search analysis from the database according to the input information and outputs past design drawings with the similarity exceeding 9;
step S8: the designer performs construction prefabrication design on the current land according to the past design drawing reference in the step S7, and when the construction cannot be subjected to block prefabrication design, the complex part parameters are independently taken out for secondary retrieval so as to obtain the past design drawing reference;
step S9: when the secondary search fails in the step S8, uploading the complex part building parameters and the building parameters of the adjacent building parts to an advanced design unit for professional design;
step S10: when the corresponding drawing is designed in the step S9, uploading the complete design drawing to a database in the step S1;
step S11: carrying out block type prefabricated parts on the building according to the complete design drawing in the step S10;
step S12: and (3) performing assembly work after the prefabricated part in the step S11 reaches the standard, and completing building construction work.
Preferably, in the step S2, the design feature information includes structural design features, building types, building households, building styles and building module segment prefabrication information of the design drawing.
Preferably, in the step S5, when the topographic information of the to-be-designed land is obtained, the surrounding environment of the to-be-designed land is measured in the field and the soil and geological information of 200 meters around the land are detected.
Preferably, in the step S5, the topographic information of the land to be designed includes topographic dimensions, altitude and climatic information.
Preferably, in step S7, when the past design drawings are output, the past design drawings are ranked according to the degree of similarity, and the past design drawing with the highest degree of similarity is output preferentially.
Preferably, in the step S8, the shape and size of the module to be designed and the load information are input when the secondary search is performed.
Preferably, in the step S9, after the complex part of the building is designed, the complex part of the building is combined with the adjacent building part by stress and the calculated stress meets the standard, if the calculated stress does not meet the standard, the complex part of the building is designed again.
Preferably, in step S10, the design drawing is labeled according to the design feature information thereof when being uploaded, and the design drawing and the labeled label are uploaded together.
The construction method for constructing the energy-saving building by adopting the prefabrication method has the beneficial effects that:
(1) The method comprises the steps of inputting a past design drawing for reference of a designer, establishing a corresponding search label according to design characteristic information of the past design drawing, establishing a search engine for the past design drawing, acquiring topographic information and architectural style information of a land to be designed by the designer, and searching similar cases in the search engine after the designer collates the topographic information and architectural style information;
(2) Through screening a plurality of past design drawings which are most similar to each other and provide reference for a designer, the designer can perform reference design according to corresponding cases, serious errors are avoided, and meanwhile design efficiency is improved;
(3) When the complex structure part of the building cannot be prefabricated in a blocking way, the parameters of the complex structure part are independently taken out for secondary retrieval, and the similar design scheme of the complex structure can be acquired in a targeted manner for a designer to refer to the design;
(4) When the secondary retrieval fails, uploading the complex part building parameters and the building parameters of the adjacent building parts to an advanced design unit for professional design, wherein the building parameters of the building parts are used for analyzing the stress problem of the complex part building by the advanced design unit, and finally uploading the complete design drawing to a database and carrying out block type prefabricated parts according to the design drawing, and carrying out assembly work after the prefabricated parts reach the standard after detection, so as to complete the building construction work;
the design of the invention improves the design conception for the designer after the existing data resources are arranged, and can also provide conception reference for the designer in the special-shaped complex structure part, thereby effectively improving the design efficiency, reducing the design error rate and being beneficial to reasonable and efficient complete building construction work.
Detailed Description
The invention is further illustrated below in connection with specific embodiments.
Examples
The construction method for constructing the energy-saving building by adopting the prefabrication method comprises the following steps of:
step S1: establishing a database, and importing past design drawings into the database;
step S2: carrying out recognition analysis on the past design drawing in the step S1 to obtain design characteristic information of the past design drawing;
step S3: establishing a corresponding retrieval label for the design drawing according to the design characteristic information of the past design drawing in the step S2 for searching;
step S4: establishing a search engine for the design drawing according to the search label in the step S3;
step S5: a designer obtains the topographic information and the architectural style information of the land to be designed, and analyzes the labels of the information;
step S6: inputting the topographic information of the land to be designed and the label to which the building style belongs in the step S5 into the search engine in the step S4 for searching;
step S7: the search engine carries out search analysis from the database according to the input information and outputs past design drawings with the similarity exceeding 9;
step S8: the designer performs construction prefabrication design on the current land according to the past design drawing reference in the step S7, and when the construction cannot be subjected to block prefabrication design, the complex part parameters are independently taken out for secondary retrieval so as to obtain the past design drawing reference;
step S9: when the secondary search fails in the step S8, uploading the complex part building parameters and the building parameters of the adjacent building parts to an advanced design unit for professional design;
step S10: when the corresponding drawing is designed in the step S9, uploading the complete design drawing to a database in the step S1;
step S11: carrying out block type prefabricated parts on the building according to the complete design drawing in the step S10;
step S12: and (3) performing assembly work after the prefabricated part in the step S11 reaches the standard, and completing building construction work.
In this embodiment, in step S2, the design feature information includes structural design features, building types, building households, building styles and building module segment prefabrication information of the design drawing, and in step S5, when the topographic information of the land to be designed is obtained, the land surrounding environment to be designed is measured in the field and the soil and geological information of 200 meters around the land are detected.
In this embodiment, in step S5, the topographic information of the land to be designed includes topographic dimensions, altitude and weather information, and in step S7, when the past design drawings are output, the past design drawings are ordered according to the similarity, and the past design drawing with the highest similarity is output preferentially.
In this embodiment, in step S8, when the secondary search is performed, the shape and size of the module to be designed and the load bearing information are input, in step S9, after the design of the complex part of the building is completed, the complex part of the building is combined with the stress of the adjacent building part and the calculated stress meets the standard, if the calculated stress does not meet the standard, the complex part of the building is designed again, in step S10, the design drawing is marked according to the design characteristic information thereof when the design drawing is uploaded, and the design drawing and the marking label are uploaded together.
The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.
Claims (8)
1. The construction method for constructing the energy-saving building by adopting the prefabrication method is characterized by comprising the following steps of:
step S1: establishing a database, and importing past design drawings into the database;
step S2: carrying out recognition analysis on the past design drawing in the step S1 to obtain design characteristic information of the past design drawing;
step S3: establishing a corresponding retrieval label for the design drawing according to the design characteristic information of the past design drawing in the step S2 for searching;
step S4: establishing a search engine for the design drawing according to the search label in the step S3;
step S5: a designer obtains the topographic information and the architectural style information of the land to be designed, and analyzes the labels of the information;
step S6: inputting the topographic information of the land to be designed and the label to which the building style belongs in the step S5 into the search engine in the step S4 for searching;
step S7: the search engine carries out search analysis from the database according to the input information and outputs past design drawings with the similarity exceeding 9;
step S8: the designer performs construction prefabrication design on the current land according to the past design drawing reference in the step S7, and when the construction cannot be subjected to block prefabrication design, the complex part parameters are independently taken out for secondary retrieval so as to obtain the past design drawing reference;
step S9: when the secondary search fails in the step S8, uploading the complex part building parameters and the building parameters of the adjacent building parts to an advanced design unit for professional design;
step S10: when the corresponding drawing is designed in the step S9, uploading the complete design drawing to a database in the step S1;
step S11: carrying out block type prefabricated parts on the building according to the complete design drawing in the step S10;
step S12: and (3) performing assembly work after the prefabricated part in the step S11 reaches the standard, and completing building construction work.
2. The construction method for energy-saving building construction by adopting the prefabrication method according to claim 1, wherein in the step S2, the design characteristic information includes structural design characteristics, building types, building houses, building styles and building module subsection prefabrication information of a design drawing.
3. The construction method for energy-saving building construction by adopting the prefabrication method according to claim 1, wherein in the step S5, when the topographic information of the land to be designed is obtained, the land surrounding environment to be designed is measured in the field and the soil and geological information of 200 meters around the land is detected.
4. The construction method for energy-saving building construction by adopting the prefabrication method according to claim 1, wherein the topographic information of the land to be designed in the step S5 includes topographic dimensions, altitude and climatic information.
5. The construction method for energy-saving building construction by adopting the prefabrication method according to claim 1, wherein in the step S7, when the past design drawings are outputted, the past design drawings are ordered according to the degree of similarity, and the past design drawing with the highest degree of similarity is outputted with priority.
6. The construction method for energy-saving building construction by the prefabrication method according to claim 1, wherein in the step S8, the shape and size of the module to be designed and the load information are inputted during the secondary search.
7. The construction method for energy-saving building construction by prefabrication according to claim 1, wherein in step S9, after the complex part of the building is designed, the complex part of the building is combined with the adjacent building part by stress and the calculated stress meets the standard, and if the calculated stress does not meet the standard, the complex part of the building is designed again.
8. The construction method for energy-saving building construction by adopting the prefabrication method according to claim 1, wherein in the step S10, the design drawing is marked and labeled according to the design characteristic information when the design drawing is uploaded, and the design drawing and the marked label are uploaded together.
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