CN113205251A - Comprehensive deepening design flow and process for core tube motor electric well pipeline of super high-rise building - Google Patents
Comprehensive deepening design flow and process for core tube motor electric well pipeline of super high-rise building Download PDFInfo
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Abstract
The invention discloses a comprehensive deepening design flow and a process for a core tube motor-generator well pipeline of a super high-rise building, which comprises S1, signing and filing by a general contract department of a motor-generator project paid by a stamping construction drawing; s2, establishing an electromechanical model of the super high-rise core tube and carrying out deepening design; s3, dividing the total progress of the electromechanical engineering in the high, medium and low areas of the super high-rise building; s4, splitting the construction flowing water section of the layered electromechanical pipe well pipeline according to the electromechanical engineering total progress plan by the ultrahigh-layer core barrel electromechanical model; s5, performing electromechanical flow construction on the core tube in the high, medium and low areas of the super high-rise building; s6, performing test operation on the high, medium and low-rise area electromechanical systems of the super high-rise building in a subarea manner; and S7, organizing and accepting the electromechanical system of the high, medium and low districts of the super high-rise building in a subarea manner. According to the invention, the comprehensive deepening design flow of the core tube electromechanical pipeline of the super high-rise building is controlled by the management view of an engineering construction unit and a construction general contract unit, and the construction modes of noise, clutter, messiness, pollution, waste, work occupation, disordered hoisting and the like in the construction of the core tube electromechanical pipeline well of the super high-rise building are solved.
Description
Technical Field
The invention relates to the technical field of comprehensive deepening design, processing and installation of motor-driven tube well pipelines of core tubes of super high-rise buildings, in particular to a comprehensive deepening design flow and a process of motor-driven tube well pipelines of core tubes of super high-rise buildings.
Background
The comprehensive deepening design process and the process method of the core tube electromechanical tube well pipeline of the super high-rise building refer to an electromechanical engineering progress control method for carrying out full-process control, deepening design management, mastering installation construction conditions of a layered flowing water section of the core tube electromechanical tube well and the like on the installation of the core tube electromechanical tube well of the super high-rise building.
Some drawbacks in the existing conventional super high-rise building project core tube motor-generator well installation engineering process are as follows, for example: the drawing version management of the deepened construction drawing of the core tube motor-driven pipe well is disordered, the one-time deepened design (two-dimensional deepening) of the motor-driven pipe well is not in place, an integral hoisting plan is not provided, secondary processing on a construction site is serious in noise, clutter, pollution and waste, equipment cannot be installed in the field, a reserved embedded support cannot be in place, pipe fittings cannot be matched for use, the secondary rework amount of the motor-driven pipe well of the core tube motor is large, files in the coming and going are managed in a disordered mode and the like.
The process method has the advantages that the whole installation control process of the core tube motor-pipe well of the super high-rise building is clear, the design key points and the construction flow arrangement are clearly deepened, the number of design changes generated in the conventional installation process is reduced, the engineering investment cost is reduced, the condition that no material or working surface causes work nest is avoided, the rework is greatly reduced, the installation efficiency and the construction period are accelerated, and the engineering quantity data and the installation progress of the core tube motor-pipe well of the super high-rise building can be mastered at any time. The electromechanical BIM deepening technology is popularized, and the technical application level of the building industry is improved.
Disclosure of Invention
The invention aims to provide a comprehensive deepening design flow and a comprehensive deepening design process of a core tube motor well pipeline of a super high-rise building so as to solve the problems in the background technology.
In order to achieve the purpose, the invention provides the following technical scheme: the comprehensive deepening design process and technology for the core tube motor-pipe well pipeline of the super high-rise building comprises the following steps:
s1, signing and filing the general contract department of the electromechanical engineering by paying the drawings of the construction drawings of the stamping version;
s2, establishing an electromechanical model of the super high-rise core tube and carrying out deepening design;
s3, dividing the total progress of the electromechanical engineering in the high, medium and low areas of the super high-rise building;
s4, splitting the construction flowing water section of the layered electromechanical pipe well pipeline according to the electromechanical engineering total progress plan by the ultrahigh-layer core barrel electromechanical model;
s5, performing electromechanical flow construction on the core tube in the high, medium and low areas of the super high-rise building;
s6, performing test operation on the high, medium and low-rise area electromechanical systems of the super high-rise building in a subarea manner;
and S7, organizing and accepting the electromechanical system of the high, medium and low districts of the super high-rise building in a subarea manner.
Preferably, the process of signing for filing by the general electromechanical engineering contractor in the step S1 includes one or more of the following operations:
the construction drawing of the stamping version handed over to the general contracting department of the electromechanical engineering by a construction unit comprises at least 1 part of an electronic file drawing file and 3 parts of paper file drawing files, and drawing handing over certification materials signed by all parties, after the general contracting department of the electromechanical engineering signs the construction drawing of the stamping version, the electronic file drawing file, the 1 part of the paper file drawing file and the drawing handing over certification materials are filed, the electronic file drawing file and the 1 part of the paper file drawing file are issued to each room, each room analyzes and feeds back to a business department, the business department and the electromechanical department are combined to carry out market research on electromechanical equipment manufacturers, and the electromechanical department compiles a comprehensive deepened design scheme, a special construction scheme and a general schedule of a construction period of an electromechanical well pipeline of a core cylinder.
Preferably, each of the chambers includes a business portion, an engineering portion, and an electromechanical portion.
Preferably, the market research comprises the production qualification, the built project, the deepened matching process, the size data of the electromechanical equipment, the engineering capacity, the production period and the installation capacity of the involved electromechanical manufacturers.
Preferably, the step S2 specifically includes:
an electromechanical deepening design department in an electromechanical engineering general contract department or an electromechanical engineering general contract department carries out full-professional full-equipment modeling work on electromechanical tube wells in a core tube area of the super high-rise building according to the drawing content of a stamping construction drawing, after the modeling is finished, a project amount list of a core tube of a standard layer of the super high-rise building is derived according to model project amount, and the model and the list are archived and backed up;
and deepening the modeling model once, taking over the achievement file after deepening by an electromechanical deepening design department to hold an electromechanical tube well checking conference of the core tube of the standard layer of the super high-rise building, and auditing the inside of an electromechanical engineering general contract department.
Preferably, the auditing of the interior of the general electromechanical engineering contract department includes auditing by a manager department, an electromechanical deepened design department, an electromechanical engineering department, a business department and a progress planning department, the auditing key points include technical auditing, installation auditing, engineering quantity auditing and preliminary auditing of engineering installation progress, if the auditing is not passed, the electromechanical deepened design department continues to deepen and modify the model according to auditing opinions, and if the auditing is passed, the deepened model, the deepened drawing and auditing opinion document are archived and backed up.
Preferably, the deepening the modeling model for one time comprises deepening the electromechanical pipeline arrangement and position information in the core cylinder electromechanical pipe well, the size and the position of the support and the electromechanical reserved embedded part, and the size and the arrangement condition of main electromechanical equipment.
Preferably, the step S3 specifically includes:
and after receiving a construction period node required by a construction unit and a time node for constructing the main structure of the super high-rise building, arranging the electromechanical engineering total progress plan of the super high-rise building, and reasonably arranging the electromechanical engineering total progress plan of high and medium-low areas of the super high-rise building and the electromechanical subsection installation plan of the high and medium-low areas according to the particularity of the super high-rise building.
Preferably, the total electromechanical engineering progress plan of the super high-rise building should take the construction condition of the main building, the equipment scheduling approach time, the hoisting plan and the actual installation requirement factors of the electromechanical engineering into consideration.
Preferably, the step S4 specifically includes:
and reasonably arranging the construction flowing water section of the electromechanical well pipeline which is split in a layered manner according to the electromechanical engineering total progress plan.
Preferably, the arrangement of the construction flowing water section of the electromechanical tubular well pipeline split in layers refers to a large-penetration construction mode of electromechanical specialties.
Preferably, the electromechanical professional large-insertion construction mode is that electromechanical pre-embedding and lightning-proof grounding work is carried out on the N layers in cooperation with the construction progress of the main body structure; the N-1 layer is used as a core cylinder reserved hole for water stop, and the net height size positioning rechecking work is carried out; the N-2 layer is used as an electromechanical reserved hole for secondary bricklaying of the core barrel, and an electromechanical support hanger or a stress member of connecting equipment is installed for working; the N-3 layers are used for installing electromechanical equipment in the core cylinder and installing a main pipeline; the N-4 layers are used for the butt joint and ring crossing work of the core cylinder and the public pipeline.
Preferably, the step S5 specifically includes:
electromechanical construction is carried out according to the split arrangement of the layered electromechanical pipe well pipeline construction flowing water section in S4, the installation and falling situation of core barrel electromechanical pipe well equipment, electromechanical equipment installation time nodes and the hoisting arrangement of the super high-rise electromechanical equipment materials are required to be checked, and the problems are required to be solved in advance.
Preferably, the step S6 specifically includes:
when the electromechanical system of the high, medium and low areas of the super high-rise building is subjected to the zone test, the electromechanical device single body debugging and the electromechanical system linkage debugging operation are carried out firstly, so that the personnel of equipment manufacturers are ensured to debug on site, and the construction operation of other areas cannot be influenced when each area is subjected to the test operation.
Preferably, the step S7 specifically includes:
before formal acceptance, the interior of the general contract department of the electromechanical engineering is subjected to acceptance pre-examination, and the work of the project data integrity and the reliability scheme of the operation of electromechanical equipment is ensured aiming at the electromechanical installation engineering of the core tube well of the super high-rise building.
Compared with the prior art, the invention has the beneficial effects that:
the invention comprehensively deepens the design flow control of the core tube electromechanical pipelines of the super high-rise building, performs the control with the management view angles of engineering construction units and construction general contract units, performs the full-flow management of the core tube electromechanical tubular well installation of the super high-rise building, and performs a new control method for the deepening design flow, the construction cooperation flow, the main nodes, the key areas, the deepening schemes, the construction period arrangement, the cost control, the quality supervision and the like by using a new technology and a new method. The construction modes of noise, disorder, pollution, waste, work nesting, disordered hoisting and the like in the construction of the core tube motor-driven tube well of the super high-rise building are solved.
Drawings
FIG. 1 is a general flow diagram of the present invention;
FIG. 2 is a main flow block diagram of the present invention;
FIG. 3 is a two-dimensional schematic diagram of a core barrel motor well according to one embodiment of the present invention;
FIG. 4 is a three-dimensional schematic diagram of a core tube electromechanical strong electric well deepening at one time according to an embodiment of the present invention;
fig. 5 is a three-dimensional schematic view of a core barrel electromechanical well deepened at one time according to an embodiment of the invention.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
Referring to fig. 1-5, the present invention provides a technical solution: the comprehensive deepening design process and the process of the electric pipe well pipeline of the core barrel machine of the super high-rise building comprise each stage from drawing receiving to organization acceptance checking.
The operations of the first, the second and the third in the figure 1 are the construction drawing of the stamping version handed over from the construction unit to the general contract department of the electromechanical engineering, and comprise at least 1 part of electronic document drawing file and 3 parts of paper document drawing file, and are handed over proving materials signed by all parties. After the general contract department of the electromechanical engineering signs the construction drawing of the stamping version, the electronic file drawing file, 1 part of paper file drawing file and drawing handover certification material are filed, and the electronic file drawing file and 1 part of paper file drawing file are issued to the business department, the engineering department, the electromechanical department and the like. Each room analyzes the equipment machine room and feeds back the equipment machine room to the business department, and the electromechanical department compiles a deepened design scheme, a special construction scheme and construction period of the core tube electromechanical well and roughly arranges the equipment machine room and the business department. The business department and the electromechanical department are combined to carry out market research on electromechanical equipment manufacturers. The method comprises the steps of investigating and researching the production qualification, the built project, the deepened matching process, the size data of the electromechanical equipment, the engineering productivity, the production period, the installation capacity and the like of the electromechanical equipment manufacturer.
The operation of the fourth step in fig. 1 is that the electromechanical engineering general contract or the electromechanical deepened design department inside the electromechanical engineering general contract should perform modeling work of all professional and all equipment on the core tube electromechanical tube well according to the drawing content of the stamping construction drawing. And after modeling is finished, deriving a project quantity list of the tubular motor well project of the core barrel of the standard layer according to the model project quantity, and archiving and backing up the model and the list. The core barrel model establishing content comprises the following steps:
civil engineering condition model components (including wall beam, plate, column and door, equipment foundation, reserved opening and the like) of the electromechanical tubular well;
all electromechanical devices of the electromechanical tube well (including components such as a distribution box cabinet, a bus, a high-voltage cable, a weak elevator frame, a weak current cabinet, a main water supply and drainage pipeline, a main fire-fighting pipeline, main pipelines of all air pipe systems and the like);
all the electromechanical pipelines and accessories (water-containing pipe fittings, air pipe fittings, lamps, socket switches, fire detectors, bridges, valves, connecting elbows, wall-penetrating sleeves, flexible connections, instruments and other components) of the machine room.
The operation of the fifth step in the figure 1 is to deepen the preliminary modeling model for one time according to the deepening design scheme in the second step, and the main deepening contents are the information of the size positioning and the main arrangement of the electromechanical equipment in the electromechanical pipe well, the size positioning of all pipelines and the like. The deepening main points of core section of thick bamboo electromechanical pipe well include: the method comprises the steps of optimizing the arrangement of the electrical equipment in the pipe well (a power distribution cabinet, a weak current cabinet, a bus bridge, a high-voltage cable, a weak current elevator frame, a water system main pipe component and other electromechanical equipment), and optimizing the branch path of the electrical pipeline in the pipe well (the conditions that the main pipeline of each electromechanical system is routed to the branch pipeline on the layer and the pipeline operation and maintenance space of the electromechanical equipment of the pipe well are ensured and the like in the electromechanical pipeline on the layer).
The operation of the sixth step in fig. 1 is that the mechanical and electrical engineering general contract department reviews the once deepened model of the mechanical and electrical tubular well of the core tube of the standard layer of the mechanical and electrical deepened design department, and the review covers: technical auditing, installation auditing and engineering quantity auditing. And ensuring that the electromechanical information in the once deepened model is in a constructable and installable state. The review points comprise: the equipment comprises equipment base (including floor and wall-hung installation) installation nodes, equipment pipeline installation nodes, bus bridge branch pipeline installation nodes, distribution cabinet inlet and outlet cable installation nodes, flexible connection installation nodes, trunk and branch pipeline pipe fitting installation nodes, pipeline accessory installation nodes, pipeline valve operation reserved space nodes, pipeline clamp flange welding installation nodes, pipeline support and hanger reserved installation nodes, equipment operation reserved space nodes, equipment replacement and transportation operation reserved space nodes and the like. And rechecking the condition of the project amount list containing the above auditing points. And comparing the data with the primary modeling model engineering quantity list, recording and backing up files. And if the audit is not passed, the electromechanical deepening design part continues to deepen and modify the model according to the audit suggestion. And if the examination is passed, archiving and backing up the primary deepened model, the primary deepened drawing, the examination opinion document and the like.
The operation of the operation formula (c) in fig. 1 is the division of the total progress of the electromechanical engineering in the high, medium and low areas of the super high-rise building, and is formulated according to the construction progress plan of the main structure of the super high-rise building, the electromechanical progress requirements of the construction units, and the construction period and nodes contained in the contract, and the factors such as the construction condition of the main building, the equipment scheduling approach time, the hoisting plan, the actual installation requirements of the electromechanical engineering and the like are considered.
The operation of the method ((I) in the figure 1) is to split the pipeline construction flowing water section of the layered electromechanical well by the electromechanical model of the ultra-high-rise core tube according to the electromechanical engineering general progress plan, namely to carry out the matching operation of the flowing water sections (large penetration construction operation) of different procedures along with the construction of the main structure during the construction of the electromechanical well of the core tube of the standard layer, and to carry out the electromechanical pre-embedding, lightning protection grounding and other operations according to the construction progress of the matched main structure of the N layers; the N-1 layer is used as a reserved hole of the core cylinder for water stop, net height size positioning rechecking and the like; the N-2 layer is used as an electromechanical reserved hole for secondary bricklaying of the core barrel, and an electromechanical support hanger or a stress member of connecting equipment is installed; the N-3 layers are used for installing electromechanical equipment in the core cylinder, installing main pipelines and the like; the N-4 layers are used for the butt joint and ring crossing of the core cylinder and the public pipeline. All electromechanical equipment pipelines are installed according to the standard requirements of national design acceptance specifications, drawing sets and the like. In the construction process, the rechecking of the approach time of the pipeline material of the electromechanical equipment, the hoisting plan arrangement and the reservation of the working interface is fully made.
The operation indicated by the ninthly in fig. 1 is to perform review of the general contractor division of the electromechanical engineering by the division scheme and the construction plan arrangement of the construction flowing water section of the electromechanical layered electromechanical pipe well pipeline of the ultra-high-rise core tube, wherein the review covers: technical rechecking, installation rechecking, engineering quantity rechecking and comprehensive construction period rechecking ensure that the construction technology and the process flow in the actual installation process meet the national standard and environmental protection requirements. If the module does not pass the audit, the module should be reworked and trimmed. And the audit files in all the processes are required to be sorted and filed. A sample plate layer for installing the electromechanical tube well is made on a certain elevation layer in a low region, and covers an equipment base (including floor and wall-hanging installation) installation node, an equipment pipeline installation node, a bus bridge branch pipeline installation node, a distribution cabinet inlet and outlet cable installation node, a flexible connection installation node, a trunk and branch pipeline pipe fitting installation node, a pipeline accessory installation node, a pipeline valve operation reserved space node, a pipeline clamp flange welding installation node, a pipeline support hanger reserved installation node, an equipment operation reserved space node, an equipment replacement transportation operation reserved space node and the like of the electromechanical tube well.
Denoted in the figure,The operation of the method is that the core tube electromechanical well pipeline in the high, middle and low areas of the super high-rise building is constructed according to the requirements in the eight and the nine, the electromechanical installation meets the plan requirements such as the standard, and the construction safety is required to be paid attention to in the construction process.
When the electromechanical system in the high, medium and low areas of the super high-rise building is subjected to the partition test, operations such as electromechanical equipment single body debugging, electromechanical system linkage debugging and the like are carried out, and personnel on site debugging of equipment manufacturers is guaranteed. When each area is tried to operate, the construction operation of other areas cannot be influenced.
Before formal acceptance, the interior of the general contract department of the electromechanical engineering is subjected to acceptance pre-examination, and the work of the project data integrity and the reliability scheme of the operation of electromechanical equipment is ensured aiming at the electromechanical installation engineering of the core tube well of the super high-rise building.
The comprehensive deepening design flow and the general flow chart of the process method of the core tube motor-well pipeline of the super high-rise building clearly describe the function of the deepening design of the core tube motor-well pipeline of the super high-rise building and the control factors of the important and difficult points.
As shown in fig. 2, the deepening design main flow chart of the comprehensive deepening design flow and the deepening design process of the core tube motor-well pipeline of the super high-rise building according to the embodiment of the invention includes:
s1, signing and filing the general contract department of the electromechanical engineering by paying the drawings of the construction drawings of the stamping version;
the construction drawing of the stamping version handed over to the general contract department of electromechanical engineering by a construction unit comprises at least 1 part of an electronic file drawing file and 3 parts of a paper file drawing file, and is handed over certification materials signed by all parties, after the general contract department of electromechanical engineering signs the construction drawing of the stamping version, the electronic file drawing file, the 1 part of the paper file drawing file and the drawing handing over certification materials are filed, the electronic file drawing file and the 1 part of the paper file drawing file are issued to a business department, an engineering department and an electromechanical department, each room analyzes and feeds back equipment to the business department, the business department and the electromechanical department are combined to carry out market research on electromechanical equipment manufacturers, and the electromechanical department compiles a comprehensive deepened design scheme, a special construction scheme and a construction period of an electromechanical well pipeline of a core cylinder.
S2, establishing an electromechanical model of the super high-rise core tube and carrying out deepening design;
an electromechanical deepening design department in an electromechanical engineering general contract department or an electromechanical engineering general contract department carries out full-professional full-equipment modeling work on electromechanical tube wells in a core tube area of the super high-rise building according to the drawing content of a stamping construction drawing, after the modeling is finished, a project amount list of a core tube of a standard layer of the super high-rise building is derived according to model project amount, and the model and the list are archived and backed up;
the modeling model is deepened once, the deepening content specifies the electromechanical pipeline arrangement and position information in the electromechanical pipe well of the core barrel, the sizes and positions of the support and the electromechanical reserved embedded parts, and the sizes and arrangement conditions of main electromechanical equipment, and the deepened achievement file is used by an electromechanical deepening design department to hold a core barrel electromechanical pipe well checking conference of a standard layer of a super high-rise building and is audited in an electromechanical engineering general contract department.
The electromechanical engineering general contract department carries out auditing, wherein the auditing comprises a manager department, an electromechanical deepened design department, an electromechanical engineering department, a business department and a progress planning department, the auditing key points comprise the aspects of technical auditing, installation auditing, engineering quantity auditing and preliminary auditing of engineering installation progress, if the auditing is not passed, the electromechanical deepened design department continues to deepen and modify the model according to auditing opinions, and if the auditing is passed, the deepened model, the deepened drawing and auditing opinion document are filed and backed up.
S3, dividing the total progress of the electromechanical engineering in the high, medium and low areas of the super high-rise building;
and after receiving the construction period node required by a construction unit and the time node for constructing the main structure of the super high-rise building, arranging the electromechanical engineering total progress plan of the super high-rise building. Aiming at the particularity of the super high-rise building, a total progress plan of electromechanical engineering in high and medium-low areas of the super high-rise building and a subsection installation plan of the electromechanical in the high and medium-low areas are reasonably arranged.
The total electromechanical project progress plan of the super high-rise building is made according to the main construction progress plan of the super high-rise building, the electromechanical progress requirements of a construction unit and construction period and nodes contained in a contract, and factors such as the construction condition of the main building, equipment scheduling approach time, a hoisting plan, the actual installation requirements of the electromechanical project and the like are considered.
S4, splitting the construction flowing water section of the layered electromechanical pipe well pipeline according to the electromechanical engineering total progress plan by the ultrahigh-layer core barrel electromechanical model;
and the super high-rise core barrel electromechanical model is used for splitting a construction flowing water section of a layered electromechanical pipe well pipeline according to an electromechanical engineering total progress plan. According to the electromechanical total progress plan, the construction flow section of the electromechanical tubular well pipeline which is split in a layered mode is reasonably arranged, the efficiency is improved, and the labor is avoided due to the fact that no material exists and no working face exists.
The arrangement of the construction flowing water section of the electromechanical tubular well pipeline which is split in layers refers to a large-penetration construction mode of electromechanical specialties. The N layers are matched with the construction progress of the main structure to perform the work of electromechanical reservation and pre-burying, lightning protection and grounding and the like; the N-1 layer is used as a reserved hole of the core cylinder for water stop, net height size positioning rechecking and the like; the N-2 layer is used as an electromechanical reserved hole for secondary bricklaying of the core barrel, and an electromechanical support hanger or a stress member of connecting equipment is installed; the N-3 layers are used for installing electromechanical equipment in the core cylinder, installing main pipelines and the like; the N-4 layers are used for the butt joint and ring crossing of the core cylinder and the public pipeline.
S5, performing electromechanical flow construction on the core tube in the high, medium and low areas of the super high-rise building;
the electromechanical flow construction of the core tube in the high, medium and low areas of the super high-rise building is carried out according to the split arrangement of the layered electromechanical tube well pipeline construction flow section in S4. The installation and placement conditions of the core barrel electromechanical tube well equipment, electromechanical equipment installation time nodes and the hoisting arrangement of the super high-rise electromechanical equipment materials are rechecked, and the problems are solved in advance.
S6, performing test operation on the high, medium and low-rise area electromechanical systems of the super high-rise building in a subarea manner;
when the electromechanical system in the high, medium and low areas of the super high-rise building is subjected to the partition test, operations such as electromechanical equipment single body debugging, electromechanical system linkage debugging and the like are carried out, and personnel on site debugging of equipment manufacturers is guaranteed. When each area is tried to operate, the construction operation of other areas cannot be influenced.
S7, performing partition organization acceptance of the electromechanical system of the high, medium and low districts of the super high-rise building;
before formal acceptance, the interior of the general contract department of the electromechanical engineering is subjected to acceptance pre-examination, and the work of the project data integrity and the reliability scheme of the operation of electromechanical equipment is ensured aiming at the electromechanical installation engineering of the core tube well of the super high-rise building.
As shown in fig. 3, 4, and 5, which are a two-dimensional schematic diagram of a core tube electromechanical tube well, a three-dimensional schematic diagram of a core tube electromechanical tube well for a once deepening of a core tube electromechanical tube well, and a three-dimensional schematic diagram of a core tube electromechanical tube well for a once deepening of a core tube electromechanical tube well of an ultra high-rise project, respectively, according to an embodiment of the present invention, specific details of steps of a method according to an embodiment of the present invention may refer to the details of the steps of the method according to the embodiment shown in fig. 1 and 2, and are not repeated herein.
In the embodiment of the invention, the comprehensive deepening design flow control of the core tube electromechanical pipelines of the super high-rise building is carried out, the management view angles of engineering construction units and construction general contract units are used for carrying out the control, the full-flow management is carried out on the installation of the core tube electromechanical pipelines of the super high-rise building, and a new control method is used for mainly carrying out the deepening design flow, the construction matching flow, the main nodes, the key areas, the deepening schemes, the construction period arrangement, the cost control, the quality supervision and the like by using a new technology and a new method. The construction modes of noise, disorder, pollution, waste, work nesting, disordered hoisting and the like in the construction of the core tube motor-driven tube well of the super high-rise building are solved.
Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.
Claims (10)
1. The comprehensive deepening design process and the process for the core tube motor-pipe well pipeline of the super high-rise building are characterized by comprising the following steps of:
s1, signing and filing the general contract department of the electromechanical engineering by paying the drawings of the construction drawings of the stamping version;
s2, establishing an electromechanical model of the super high-rise core tube and carrying out deepening design;
s3, dividing the total progress of the electromechanical engineering in the high, medium and low areas of the super high-rise building;
s4, splitting the construction flowing water section of the layered electromechanical pipe well pipeline according to the electromechanical engineering total progress plan by the ultrahigh-layer core barrel electromechanical model;
s5, performing electromechanical flow construction on the core tube in the high, medium and low areas of the super high-rise building;
s6, performing test operation on the high, medium and low-rise area electromechanical systems of the super high-rise building in a subarea manner;
and S7, organizing and accepting the electromechanical system of the high, medium and low districts of the super high-rise building in a subarea manner.
2. The super high-rise building core tube motor well pipeline comprehensive deepening design process and technology of claim 1 are characterized in that: the process of signing and filing the signature of the signing and filing of the construction drawing of the stamping version in the step S1 by the general electromechanical engineering contractor includes one or more of the following operations:
the construction drawing of the stamping version handed over to the general contracting department of the electromechanical engineering by a construction unit comprises at least 1 part of an electronic file drawing file and 3 parts of paper file drawing files, and drawing handing over certification materials signed by all parties, after the general contracting department of the electromechanical engineering signs the construction drawing of the stamping version, the electronic file drawing file, the 1 part of the paper file drawing file and the drawing handing over certification materials are filed, the electronic file drawing file and the 1 part of the paper file drawing file are issued to each room, each room analyzes and feeds back to a business department, the business department and the electromechanical department are combined to carry out market research on electromechanical equipment manufacturers, and the electromechanical department compiles a comprehensive deepened design scheme, a special construction scheme and a general schedule of a construction period of an electromechanical well pipeline of a core cylinder.
3. The super high-rise building core tube motor well pipeline comprehensive deepening design process and technology of claim 2 are characterized in that: each room comprises a business part, an engineering part and an electromechanical part.
4. The super high-rise building core tube motor well pipeline comprehensive deepening design process and technology of claim 2 are characterized in that: the market research comprises the production qualification, the built project, the deepened matching process, the size data of the electromechanical equipment, the engineering capacity, the production period and the installation capacity of the involved electromechanical manufacturers.
5. The super high-rise building core tube motor well pipeline comprehensive deepening design process and technology of claim 1 are characterized in that: the step S2 specifically includes:
an electromechanical deepening design department in an electromechanical engineering general contract department or an electromechanical engineering general contract department carries out full-professional full-equipment modeling work on electromechanical tube wells in a core tube area of the super high-rise building according to the drawing content of a stamping construction drawing, after the modeling is finished, a project amount list of a core tube of a standard layer of the super high-rise building is derived according to model project amount, and the model and the list are archived and backed up;
deepening the modeling model once, taking the lead of a deepened result file by an electromechanical deepening design department to hold an electromechanical tube well checking conference of a core tube of a standard layer of the super high-rise building, and auditing the inside of an electromechanical engineering general contract department;
the modeling model is deepened for one time, wherein the deepening content of the modeling model defines electromechanical pipeline arrangement and position information in a core cylinder electromechanical pipe well, the sizes and positions of a support hanger and an electromechanical reserved embedded part, and the sizes and arrangement conditions of main electromechanical equipment;
the electromechanical engineering general contract department carries out auditing including a manager department, an electromechanical deepened design department, an electromechanical engineering department, a business department and a progress planning department, the auditing key points include the aspects of technical auditing, installation auditing, engineering quantity auditing and preliminary auditing of engineering installation progress, if the auditing is not passed, the electromechanical deepened design department continues to deepen and modify the model according to the auditing opinions, and if the auditing is passed, the deepened model, the deepened drawing and the auditing document are filed and backed up.
6. The super high-rise building core tube motor well pipeline comprehensive deepening design process and technology of claim 1 are characterized in that: the step S3 specifically includes:
after receiving a construction period node required by a construction unit and a time node for main structure construction of the super high-rise building, arranging the electromechanical engineering total progress plan of the super high-rise building, and reasonably arranging the electromechanical engineering total progress plan of high and medium-low areas of the super high-rise building and the electromechanical subsection installation plan of the high and medium-low areas aiming at the particularity of the super high-rise building, wherein the electromechanical engineering total progress plan of the super high-rise building needs to consider the construction condition of the main building, the equipment scheduling lead-in time, the hoisting plan and the actual installation requirement factors of the electromechanical engineering.
7. The super high-rise building core tube motor well pipeline comprehensive deepening design process and technology of claim 1 are characterized in that: the step S4 specifically includes:
reasonably arranging the construction flow section of the electromechanical well pipeline which is split in a layered manner according to the total electromechanical engineering progress plan;
the arrangement of the construction flow section of the electromechanical tubular well pipelines which are split in a layered mode refers to a large-insertion construction mode of an electromechanical specialty, and the large-insertion construction mode of the electromechanical specialty is that N layers are matched with the construction progress of a main body structure to perform electromechanical pre-embedded and lightning-proof grounding work; the N-1 layer is used as a core cylinder reserved hole for water stop, and the net height size positioning rechecking work is carried out; the N-2 layer is used as an electromechanical reserved hole for secondary bricklaying of the core barrel, and an electromechanical support hanger or a stress member of connecting equipment is installed for working; the N-3 layers are used for installing electromechanical equipment in the core cylinder and installing a main pipeline; the N-4 layers are used for the butt joint and ring crossing work of the core cylinder and the public pipeline.
8. The super high-rise building core tube motor well pipeline comprehensive deepening design process and technology of claim 1 are characterized in that: the step S5 specifically includes:
electromechanical construction is carried out according to the split arrangement of the layered electromechanical pipe well pipeline construction flowing water section in S4, the installation and falling situation of core barrel electromechanical pipe well equipment, electromechanical equipment installation time nodes and the hoisting arrangement of the super high-rise electromechanical equipment materials are required to be checked, and the problems are required to be solved in advance.
9. The super high-rise building core tube motor well pipeline comprehensive deepening design process and technology of claim 1 are characterized in that: the step S6 specifically includes:
when the electromechanical system of the high, medium and low areas of the super high-rise building is subjected to the zone test, the electromechanical device single body debugging and the electromechanical system linkage debugging operation are carried out firstly, so that the personnel of equipment manufacturers are ensured to debug on site, and the construction operation of other areas cannot be influenced when each area is subjected to the test operation.
10. The super high-rise building core tube motor well pipeline comprehensive deepening design process and technology of claim 1 are characterized in that: the step S7 specifically includes:
before formal acceptance, the interior of the general contract department of the electromechanical engineering is subjected to acceptance pre-examination, and the work of the project data integrity and the reliability scheme of the operation of electromechanical equipment is ensured aiming at the electromechanical installation engineering of the core tube well of the super high-rise building.
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