LU502429B1 - A construction method for lifting steel structures in combustion and cleaning chambers of power plants - Google Patents

Abstract

The present invention discloses a construction method for lifting steel structures in combustion and cleaning chambers of power plants, comprising the following steps: Step 1: Zoning: The area of the combustion chamber to the west of the tower crane used for lifting equipment is defined as Zone 1 designated, the area of the decontamination room north of the combustion room as Zone 2; the area south of the tower crane is designated as zone 3, the area to the north thereof as zone 4 and the area of the tower crane as zone 5; the assembly area for the trusses will be erected on the west, north and east side of the system; Step 2: Equipment selection: selection of crawler cranes as steel lifting equipment, truck-mounted cranes as crawler crane installation and disassembly, steel structure assembly equipment; Step 3: Construction: Use the crawler crane to do the lifting construction of zone 1 and zone 2 first; after zone 2 construction is completed, move the crawler crane to zone 4 for lifting construction; when the steel structure of zone 1 and zone 2 is under construction, carry out the lifting construction of the steel structure of zone 3 when the tower crane is free; after the tower crane removal is completed, use the mobile crane to carry out the lifting construction of the zone 5 steel structure. The application has the advantages of short cycle time, low construction cost and high security.

Description

Description LU502429 A construction method for lifting steel structures in combustion and cleaning rooms of power plants Technical Field The present invention relates to the technical field of steel construction, more particularly to a construction method for lifting steel structures in combustion and cleaning rooms of power plants. Background Technology At present, municipal solid waste in China has become an important issue affecting the development of our cities. China's waste production is huge and is now mainly treated by incinerating waste to generate energy. Boiler is a kind of energy conversion equipment. The energy supplied to the boiler is the chemical energy in the fuel, electrical energy. The boiler emits steam, high-temperature water or organic heat carriers with a certain amount of thermal energy. The hot water or steam generated in the boiler can be directly used for industrial production and people's life to provide the required thermal energy, but also can be converted into mechanical energy through the steam power plant, or then through the generator to produce mechanical energy ın to convert electrical energy. The commonly used grate mechanical waste incineration power plants mainly consist of waste incineration and heat recovery systems, flue gas cleaning systems, auxiliary processes and other systems, all of which are essentially concentrated in the main plant.

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Description LU502429 The main facility is mostly a steel structure building, the steel structure in the process of construction, need to use the steel structure lifting structure with the crane will be lifting the steel structure. However, the current steel structure construction and incineration equipment installation and flue gas cleaning equipment installation boiler is generally successive construction, equipment using tower cranes for installation, the steel structure using crawler cranes for installation, but for some tight schedule requirements, the use of successive construction type and way the cycle is long, and the construction cost is high, can not meet the schedule requirements.

SUMMARY OF THE INVENTION The invention provides a method of constructing steel structures in combustion and cleaning chambers of power plants with a short cycle time, low construction costs and high safety.

The technical problem is solved: the current steel structure construction and combustion equipment installation and flue gas cleaning equipment installation boiler generally successive construction, installations using tower cranes for installation, steel structure with crawler cranes for installation, but for some tight schedule requirements, the use of consecutive Construction of the way the cycle is long, and the construction cost is high, can not meet the schedule requirements.

In order to solve the above technical problems, the following technical solutions are used in the present invention: -_———

Description LU502429

The present invention is a construction method for lifting steel structures in combustion and cleaning chambers of power plants, comprising the following steps:

Step 1: Zoning: The area of the combustion chamber west of the tower crane used for lifting equipment is designated Zone 1, the area of the decontamination chamber north of the combustion chamber is designated Zone 2; the area south of the tower crane is designated as zone 3, the area to the north thereof as zone 4 and the area of the tower crane as zone 5; the assembly area for the trusses will be erected on the west, north and east side of the system; Step 2: Equipment selection: selection of crawler cranes as steel lifting equipment, truck-mounted cranes as crawler crane installation and disassembly, steel structure assembly equipment, crawler cranes according to the lifting radius of the tower crane, its own lifting radius, lifting capacity and the height of the equipment, choose the appropriate specifications of the lifting weight and boom length; Step 3: Construction: The crawler crane travel route is driven out from the north side of the factory from zone 2 to the northwest corner of zone 2, then through the north side from the north-east corner of zone 4 to zone 4, the travel route is hardened, the Truss assembly site will be set up on the crawler crane travel route in zone 2, the northeast corner of the factory, the northwest corner of the factory and the east side of the factory; with the crawler crane, the first zone lifting operations are carried out first, and after the completion of the first zone lifting operations, the second zone lifting operations are carried out, with the first and second zones in reverse construction method ————————

Description LU502429 run. moving the crawler crane to zone four to lift structures after completing work in zone two; construction of steel structures in Zone 1 and Zone 2 interrupted by lifting of steel structures in Zone 3 during periods when the tower crane is not lifting equipment; after the dismantling of the tower crane was completed, the steel structure in zone 5 was lifted with a truck-mounted crane.

The present invention relates to a construction method for lifting steel constructions in combustion and cleaning chambers of power plants. In step 1, the truss assembly location on the crawler crane travel route is used for the steel structure assembly of Zone 1 and Zone 2, the truss assembly location in the northwest corner of the facility is used for the steel structure assembly of Zone 2, the location of Truss assembly in the northeast corner of the facility is used for assembling Zone 4 steel structure, the assembly location on the east side of the facility near the tower crane is used for assembling Zone 3 and Zone 5 steel structure.

The present invention relates to a construction method for lifting steel constructions in combustion and cleaning chambers of power plants. In step 3, the crawler crane stands on the west side of the boiler to lift the lattice columns, wall trusses, main trusses, secondary trusses and tie rods one by one, the crawler crane is used for lifting in areas not covered by the crawler crane; after installation in zone 1 is completed, reverse assembly procedure for lifting lattice supports, main trusses, ————————

Description LU502429 Secondary truss and tie rods used in sequence in Zone 2.

The present invention relates to a construction method for lifting steel constructions in combustion and cleaning chambers of power plants. Two area steel structure is completed, crawler crane from the north side of the four area into the four area for lattice support, main truss, secondary truss and tie rods lifting.

The present invention relates to a construction method for lifting steel constructions in combustion and cleaning chambers of power plants. Secondary truss and connecting rod installation shall be prior to the completion of the roof secondary truss and connecting rod installation on the plant to determine whether the equipment will affect installation. If this is the case, the device is installed first, and then the secondary beam and tie rod are installed; if not, the secondary beam and tie rod are installed.

The present invention relates to a construction method for lifting steel constructions in combustion and cleaning chambers of power plants. When lifting the main and secondary girders in an area through the tower, when the center of gravity of the girders is outside the detection radius of the tower crane, a water tank is placed on the bottom chord of the girders to bring the center of gravity of the girders into the detection range of the tower crane.

The present invention relates to a construction method for lifting steel constructions in combustion and cleaning chambers of power plants. Weld I-beams to the truss bottom chords and water tank —————————

Description LU502429 to the I-beams.

The present invention relates to a construction method for lifting steel constructions in combustion and cleaning chambers of power plants. In the steel structure before welding, in the fabrication shop drawings deepening of the node design center coordinates into the physical surface of the three-dimensional coordinates, the components in front of the factory in the outer surface of the components marked cross-center position, and marked with eye-catching color , at the same time in the design drawings to set the point and point coordinate value; when positioning the steel structure, the center of the cross is used as the positioning point.

The present invention relates to a construction method for lifting steel constructions in combustion and cleaning chambers of power plants. The cross center marking points shall be chosen at least 300 mm inwards from the openings of the fittings, the points shall be located near the outside near the bottom and not less than three marking points shall be chosen at each node.

Compared with the prior art, the present invention has the following advantageous effects: I. The present application combines the installation of steel structures and the installation of equipments in the plant, utilizes tower cranes and crawler cranes used for equipment lifting to the subdivide the system in a sensible way, and then enables the ————————— through sensible planning of the construction sequence and the construction process of each division

Description LU502429 Cross construction of steel structures and the installation of equipment shortens the construction cycle, makes good use of the equipment and reduces construction costs.

2. Optimizing the location of finished and semi-finished steel products through rational planning of the construction roads to avoid secondary transhipment at the construction site, reduce transportation costs and shorten the construction cycle.

3. Consider the contradictions arising from the simultaneous erection of the steel structure and the installation of equipment during construction, and before installing the secondary joist and tie rod, determine whether the completion of the installation of the secondary joist and tie rod on the roof affects the installation of equipment; if this is the case, install the equipment first, and then the secondary joist and tie rod; if not, install the secondary downstand and tie bar.

4. In cases where the tower crane and crawler crane have cluttered areas in the lifting area that cause the center of gravity of the girder to be outside the coverage radius of the tower crane, a water tank will be installed on the bottom chord of the girder to keep the center of gravity of the girder within the Aligning coverage radius of tower crane and ensure the safety of lifting.

5. By converting the construction points into three-dimensional coordinates on the surface of the structural members and marking them visibly, it is easy to measure and to ——————— during later assembly of the steel structure.

Locate Description LU502429.

The present invention is described in more detail below in connection with the accompanying drawings.

Description of the accompanying drawings Figure 1 shows a schematic representation of the zone structure of the present invention.

Figure 2 shows a schematic representation of the Zone I construction structure of the present invention.

Figure 3 shows a schematic representation of the structural layout of Zone 2 of the present invention.

Figure 4 shows a schematic representation of the construction structure of Zone 3 and Zone 4 of the present invention.

Figure 5 shows a schematic representation of the construction structure of zones of the present invention.

Figure 6 shows a schematic representation of the spreader hoist of the present invention.

Figure 7 shows a schematic representation of the mounting structure of the water tank according to the present invention.

With markings:

1.Zone 1; 2.Zone 2; 3.Zone 3; 4.Zone 4; 5.Zone 5; 6. Crawler Crane; 7. Tower Crane; 8. driveway; 9. Truss assembly station; 10. Binder; 11. water tank; 12. I beam.

Detailed description -_

Description LU502429 The steel structure of the combustion chamber and the cleaning chamber of the proposed power plant consists of lattice supports, wall trusses, main trusses, secondary trusses and connecting rods.

The present invention includes a construction method for lifting steel structures in combustion and cleaning rooms of power plants, which includes the following steps: See Figure 1, Step 1: Division into zones: According to the lifting capacity of the crane machines on site, the lifting radius, the construction time of the equipment and the dismantling time of the tower crane 7, the area of the incineration room west of the tower crane 7 for lifting the equipment of the incineration room and cleaning room is set as Zone 1, and the area of the cleaning room north of the incineration room is defined as Zone 2; the area south of tower crane 7 is defined as zone 3 and the area north as zone 4 and the area of tower crane 7 as zone 5; the lattice columns and trusses 10 are assembled and sent to the site at the factory for docking section by section.

Step 2: Selection of equipment: Crawler crane 6 was selected as the lifting device for the steel structure, and the truck-mounted crane was used for the assembly, disassembly and assembly of the steel structure. The crawler crane 6 selected the appropriate lifting weight and boom length according to the lifting radius of the tower crane 7, its own lifting radius, the height and weight of the steel structure, the lifting capacity and the equipment height of the crawler crane 6 and the tower crane 7, with the _—

Description LU502429 Booms of the crawler crane 6 and the tower crane 7 must not interfere with each other.

Combined with Picture 2 - Picture 5, Step 3: Construction: The track 8 of the crawler crane 6 runs from the north side of the plant from zone 2 to the northwest corner of zone 2, and then runs from the northeast corner of zone 4 via the north side ı into the zone 4 on, the route 8 is hardened. The beam assembly station 9 is located on the route 8 of the crawler crane 6 in zone 2, in the northeast corner of the factory, in the northwest corner of the factory and on the east side of the factory. Beam assembly area 9 on route 8 of crawler crane 6 is used for steel construction assembly in Zone 1 and Zone 2. Beam assembly yard 9 at the northwest corner of the plant is intended for zone 2 steel structure assembly, beam assembly yard 9 at the northeast corner of the plant is intended for zone 4 steel structure assembly. The assembly area on the east side of the plant near the lifting area of tower crane 7 is used for assembling the steel structure in Zone 3 and Zone 5. The steel construction yard is equipped with a lifting area near the 7 tower crane to meet the lifting capacity requirements of the components. Optimize the storage location of finished and semi-finished steel structures to eliminate secondary warehouse handling and reduce transportation costs.

Use the Crawler Crane 6 to do the lifting construction of Zone 1 first; after zone 1 lift construction is completed, perform zone 2 lift construction, with zone 1 and zone 2 using reverse construction; after the construction of Zone 2 1

Description LU502429 is completed, move the crawler crane 6 for the lifting structure to zone 4; when constructing the steel structure of Zone 1 and Zone 2, break the lifting structure of the steel structure of Zone 3 during the tower crane 7 non-lifting equipment; after tower crane 7 dismantling is completed, use truck crane to get into zone 5 to lift the steel structure and erect truss assembly yard 9 in place of original tower crane 7 during construction.

Specifically, the route 8 of the crawler crane 6 runs from the north side of the factory from zone 2 to the northwest corner of zone 2, and then enters zone 4 via the north side from the northeast corner of zone 4. The route 8 is hardened and a truss assembly station 9 is set up on the route 8 of the crawler crane 6 during the construction of the steel structure in zone 1 and zone 2.

During the erection of the steel structure in Zone 1, the Crawler Crane 6 was brought into the plant from the north-west corner of the plant and positioned on the west side of the boiler to successively raise the lattice columns, wall trusses, main trusses, secondary trusses and tie rods with the Tower Crane 7 in the areas, which are not covered by the lifting range of the crawler crane 6. After completing the assembly of the steel structure in Zone 1, the truss supports, the main trusses, the secondary trusses and the tie rods in Zone 2 are raised one after the other using the reverse installation method.

Referring to Figure 6 and Figure 7, when constructing the steel structure 1

Description LU502429 of zone 1 there is a blind zone in the lifting area of the tower crane 7 and the crawler crane 6, which causes the center of gravity of the girder 10 to be outside the coverage radius of the tower crane 7. A water tank 11 is attached to the bottom chord of the girder 10 to adjust the center of gravity of the girder 10 before subsequent lifting within the coverage radius of the tower crane 7; specifically, an I-beam 12 is welded to the bottom chord of the beam 10, and the water tank 11 is welded to the I-beam 12 and fixed.

After completion of the steel structure in Zone 2, crawler crane 6 was driven into Zone 4 from the north side of Zone 4 to lift the lattice supports, main and secondary trusses and tie rods.

In addition, before installing the secondary trusses and tie rods, it is determined whether the completion of the installation of the secondary trusses and tie rods on the roof will affect the installation of the equipment; if so, the devices are installed first, and then the secondary trusses and tie rods are installed; if not, the secondary trusses and tie rods are installed.

Since at present the axial coordinates of the nodes are often given in the design drawings, these data are practically useless for the design, the reflection prism of the total station cannot stand at the position of this coordinate point, nor can the infrared penetrate the rod to reach the center , and there is no obvious angle feature point on the outer surface, the element of measurement and positioning is the point and the three-dimensional coordinate value of the point, the position of all nodes must be determined by the three-dimensional coordinates 1

Description LU502429 to determine their position, and the construction is difficult. Therefore, the coordinates of the nodal point in the design drawing are converted to 3D coordinates of the physical surface when the drawings are deepened in the factory, and the position of the cross center is marked on the outer surface of the part before it leaves the factory and with conspicuous color marked while marking the point position and point coordinate value on the design drawing; when positioning the steel structure, the position of the cross center is used as the positioning point corresponding to the position of the cross center.

The principles for selecting the marking points are: the marking point is chosen at least 300 mm from the pipe connection opening; the position of the point is near the outside near the ground, as far as possible in the same visible plane, and the distance between the points is as large as possible; no fewer than three points should be selected at each node. Where the points are selected in the node port to 300mm inside, it is to avoid welding in the steel structure, resulting in marking point position deviation, such as points near the port, welding metal melt or grinding after welding may damage the point remove, so the deviation after welding is difficult to determine the comparison. The points are near the outside near the ground, as far as possible in a visible plane, and the distance between the points is as large as possible. The first consideration is the ease of measurement since the total station is placed on the ground and 1

Description LU502429 Points in the same view plane can be observed at once, otherwise the station has to be moved twice. Measurements from a different angle from which the second measurement between will also cause a certain amount of measurement error. The distance between the points becomes larger relative to the maximum diagonal of the node, the larger the distance between the points and the ratio of the diagonal length, i.e. the higher the relative error accuracy, the higher the correct positioning of the node. Each node should have no less than 3 gage marks needed for positioning in 3D coordinate space. If only one or two points are selected, the nodes may rotate around the axis, which may affect the beam's orientation angle.

The embodiments described above are only a description of the preferred embodiment of the present invention and are not intended to limit the scope of the present invention. Without departing from the gist of the present invention, all kinds of variations and improvements made by those skilled in the art to the technical solutions of the present invention fall within the scope of protection determined by the claims of the present invention.

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Claims (9)

Claim LU502429 1. A construction method for lifting steel structures in combustion and cleaning rooms of power plants, characterized in that it comprises the following steps: Step 1: Zoning: The area of the combustion room west of the tower crane, which is used for lifting equipment, is defined as Zone 1 denotes the area of the decontamination room north of the combustion chamber as Zone 2; the area south of the tower crane is designated as zone 3, the area to the north thereof as zone 4 and the area of the tower crane as zone 5; Step 2: Equipment selection: selection of crawler cranes as steel lifting equipment, truck-mounted cranes as crawler crane installation and disassembly, steel structure assembly equipment, crawler cranes according to the lifting radius of the tower crane, its own lifting radius, lifting capacity and the height of the equipment, choose the appropriate specifications of the lifting weight and boom length; Step 3: Construction: The crawler crane travel route is driven out from the north side of the factory from zone 2 to the northwest corner of zone 2, then through the north side from the north-east corner of zone 4 to zone 4, the travel route is hardened, the Truss assembly site will be set up on the crawler crane travel route in zone 2, the northeast corner of the factory, the northwest corner of the factory and the east side of the factory; with the crawler crane, the first zone lifting operations are performed first, and after the first zone lifting operations are completed, the second zone lifting operations are performed, with the first and second zones being reversed. Moving the crawler crane to zone four to lift —=<ËŒÆHË— Claims LU502429 structures upon completion of work in zone two; construction of steel structures in Zone 1 and Zone 2 interrupted by lifting of steel structures in Zone 3 during periods when the tower crane is not lifting equipment; after the dismantling of the tower crane was completed, the steel structure in zone 5 was lifted with a truck-mounted crane. 2. A construction method for lifting steel structures in combustion and cleaning rooms of power plants according to claim 1, is characterized by the following features: In step 1, the place of truss assembly is on the route of the crawler crane for assembling the steel structure of zone 1 and zone 2 truss assembly location in the north-west corner of the facility is used for assembling zone 2 steel structure, truss assembly location in the north-east corner of the facility is used for zone 4 steel structure assembly, truss assembly location on the East side of the facility near the tower crane used for assembling the steel structure of Zone 3 and Zone 5. 3. A construction method for lifting steel structures in combustion and cleaning rooms of power plants according to claim 1, is characterized by the following features: In step 3, the crawler crane stands on the west side of the boiler, around the lattice supports, wall trusses, main trusses, secondary trusses and tie rods one after the other lifting and the crawler crane is used for lifting in areas not covered by the crawler crane; after installation in zone 1 is completed, reverse assembly procedure for lifting lattice supports, main truss, secondary truss and tie rods —=ËŒÆË— Claims LU502429 used consecutively in Zone 2. 4. A construction method for lifting steel structures in combustion and cleaning rooms of power plants according to claim 3, is characterized by the following features: Two area steel structure is completed, crawler crane from the north side of the four areas into the four areas for lattice support, main truss, secondary truss and lift tie rods. 5. A construction method for lifting steel structures in combustion and cleaning rooms of power plants according to any one of claims 3-4, is characterized by the following features: Secondary truss and connecting rod installation is prior to the completion of the roof secondary truss and connecting rod installation on the plant determine whether the equipment will affect installation. If this is the case, the device is installed first, and then the secondary beam and tie rod are installed; if not, the secondary beam and tie rod are installed. 6. A construction method for lifting steel structures in combustion and cleaning rooms of power plants according to claim 3, is characterized by the following features: When lifting the main and secondary beams in one area through the tower, when the center of gravity of the beams is outside the coverage radius of the tower crane , a water tank is placed on the lower chord of the girders in order to bring the center of gravity of the girders into the detection range of the tower crane. 7. A construction method for lifting steel structures in m Claims LU502429 Combustion and cleaning rooms of power plants according to claim 6, is characterized by the following features: I-beam, water tank and I-beam welded in the truss lower chord bar. 8. Fin construction method for lifting steel structures in combustion and cleaning rooms of power plants according to claim 1, is characterized by the following features: in the steel structure before welding, in the fabrication works drawings deepening of the node design center coordinates in the physical surface of three-dimensional coordinates, the components in front of the factory in the outer surface of the components marked cross-center position, and marked with eye-catching color, at the same time in the design drawings to show the point and point coordinate value. When positioning the steel structure, the center of the cross is used as the positioning point. 9. Fin construction method for lifting steel structures in combustion and cleaning chambers of power plants according to claim 8, is characterized by the following features: The cross center marking points will be chosen at least 300 mm inwards from the openings of the fittings, the points close to the outside are located close to the ground and no fewer than three markers are chosen at each node. -_———