CN206917351U - The whole self-propelled totally-enclosed green construction enclosing of formula - Google Patents

Abstract

The integral self-propelled fully enclosed green construction enclosure disclosed by the utility model comprises a main structure, a truss vehicle system and a walking system. Wherein, the main structure includes the main frame, the walls arranged around the main frame and the roof arranged on the top of the main frame, and the wall and the roof form a closed space; the walking system includes Guide rails, guide wheels, drives and transmissions on side foundations. The construction enclosure provided by the utility model adopts a fully enclosed structure, which isolates noise, dust, and bright light, creates a better construction surrounding environment, and reduces the impact on residents. The subway construction can be moved freely along the line, avoiding repeated installation and dismantling work, reducing the workload, reducing the construction cost and improving the construction efficiency.

Description

Integral self-propelled fully enclosed green construction fence

technical field

The utility model relates to an integral self-propelled fully enclosed green construction enclosure, which belongs to the field of engineering construction.

Background technique

Nowadays, with the continuous development of cities, the development and utilization of underground space is becoming more and more popular, especially the number and coverage of subway construction have become an indicator to measure the economic development of a city. However, subway stations are mostly located in densely populated areas, and construction pollution such as sound, light, and dust brought about by large-scale, long-period underground construction during subway construction has a greater impact on surrounding residents. In particular, the subway project that adopts the open-cut method will have a greater impact on the surrounding residents.

In order to reduce the impact of the open-cut method on the surrounding residents, the existing technology mostly adopts closed facilities such as shading sheds and enclosures for closed operations to prevent the spread of sound, light and dust. However, the construction area involved in the subway project is relatively large, and the construction area needs to be closed in sections, and the closed facilities such as sunshades and enclosures need to be turned around many times. However, the existing fixed closure method requires repeated disassembly and assembly of the closure facility, the construction process is cumbersome, the construction efficiency is low, and it cannot meet the requirements of efficient construction.

Utility model content

Aiming at the problems of cumbersome procedures and low efficiency in the turnover of closed facilities such as sun-shading sheds and enclosures in the prior art, the utility model provides an integral self-propelled fully enclosed green construction enclosure, which adopts a fully enclosed structure and will Noise, dust, and bright light are isolated to create a better construction surrounding environment and reduce the impact on residents. At the same time, the walking system is adopted to enable the fully enclosed construction enclosure to move freely along the subway construction line, avoiding repeated installation and removal. The workload is reduced, the construction cost is reduced, and the construction efficiency is improved.

In order to solve the above technical problems, the utility model includes the following technical solutions:

An integral self-propelled fully enclosed green construction enclosure, including:

The main structure includes the main frame, the walls arranged around the main frame and the roof arranged on the top of the main frame, and the wall and the roof form a closed space; the main frame includes Bottom beams arranged sideways and in parallel, several columns fixed on the bottom beams, cross bars and oblique bars arranged between the columns, and top roof trusses arranged above the columns and across the construction area; The walls corresponding to the two ends of the bottom beam are provided with rolling doors;

The truss car system includes a hoisting truss car across the construction area, a truss car track located at both ends of the hoisting truss car, a truss car beam located under the truss car track, and a cow set on the column Legs, the truss girder is fixedly arranged on the corbel;

The walking system includes guide rails arranged on the foundations on both sides of the construction area, guide wheels arranged under the bottom beam, a driving device arranged on the main frame, and a transmission connecting the driving device and the guide wheels device.

Further, the transmission device includes a brake wheel coupling, a speed reducer, and a shaft coupling connected in sequence, the brake wheel coupling is connected to the driving device, and the shaft coupling is connected to the guide wheel .

Further, the construction enclosure also includes a control room, which is arranged on the main frame and connected to the ground through a ladder.

Further, the construction enclosure also includes an intelligent monitoring platform, the intelligent monitoring platform includes intelligent monitoring equipment, a data server for receiving and storing the monitoring data of the intelligent monitoring equipment, and a data server for displaying monitoring data and manipulating the intelligent monitoring equipment. Smart terminal for monitoring equipment.

Further, the intelligent monitoring equipment includes at least one of the following:

A global eye, the global eye is arranged on the main frame and/or on the lifting truss;

A capture device, the capture device is set facing the door;

Aerial camera, the aerial camera is set in the construction enclosure;

An environment detector, the environment detector is arranged on the lifting truss truck and/or the main frame.

Further, an intelligent sprinkler system is also provided in the construction enclosure, and the intelligent sprinkler system includes a water storage tank, a high-pressure water pump, a liquid delivery pipe, a flexible pipe and a spray pipe connected in sequence, and also includes a The slide rail is suspended on the top roof truss, the spray pipe is suspended on the lifting truss truck, and a plurality of nozzles are arranged at intervals on the spray pipe; the high-pressure water pump is connected with A microprocessor, which includes a water pump on-off switch for controlling the high-pressure water pump and a water pump speed controller for controlling the speed of the high-pressure water pump; the microprocessor is also connected to a humidity detector.

Preferably, a plurality of strip-shaped or block-shaped fiberglass lighting strips are arranged at intervals on the roof.

Preferably, the melting point of the FRP lighting belt is 100°C to 200°C.

Preferably, the upper edge of the wall is higher than the lower edge of the roof, an inner gutter is arranged between the wall and the roof, the inner gutter communicates with the upper end of the rainwater pipe, and the lower end of the rainwater pipe extends out of the wall.

Compared with the prior art, the utility model has the following advantages and positive effects due to the adoption of the above technical scheme:

(1) It can isolate noise, dust and bright light to create a better construction surrounding environment and reduce the impact on residents;

(2) The fully enclosed environment can prevent the impact of extreme weather such as rain, snow, and wind on the construction, and can also ensure the continuity of night construction and shorten the construction period to the greatest extent;

(3) The roof of the construction enclosure is inlaid with glass lighting strips to ensure the lighting effect, and the lighting strips are made of materials that melt when exposed to open flames, and become smoke exhaust channels in case of fire to ensure the personal safety of construction workers in the construction area;

(4) The spray system combined with the hoisting truss truck is installed in the construction enclosure, which realizes the mobile spray and automatic spray of the spray system, and can effectively spray the dust source on the working surface of the construction area , thereby reducing the dust content in the air in the construction area, improving the construction environment for workers, and effectively reducing water consumption;

(5) An intelligent detection platform is installed in the construction enclosure, which can monitor humidity, temperature, noise, solid particle concentration, vehicles entering and leaving, construction scenes, etc., and control the construction information in the construction enclosure in real time.

(6) By carrying the walking system, the fully enclosed construction fence can be moved freely along the subway construction line, and can be easily moved from one construction bid section to another construction bid section, avoiding repeated installation and dismantling work, not only saving A lot of time and cost can keep up with the fast-paced subway construction, and maximize the scope of application and coverage of fully enclosed construction enclosures.

Description of drawings

Fig. 1 is the cross-sectional view of the integral self-propelled fully enclosed green construction enclosure provided by the first embodiment of the utility model;

Fig. 2 is the front view of construction enclosure;

Fig. 3 is the side view of construction enclosure;

Fig. 4 is a sectional view of the corbel and the truss car track;

Fig. 5 is a schematic structural diagram of the walking system;

Fig. 6 is a connection relationship block diagram of the intelligent monitoring platform provided by the second embodiment of the utility model;

Fig. 7 is a schematic structural diagram of the intelligent spraying system provided by the third embodiment of the present invention;

Fig. 8 is a flow chart of the construction method of the fully enclosed green construction enclosure provided by the fourth embodiment of the present invention.

The numbers in the figure are as follows:

Construction fence 100; main structure 110; main frame 111, bottom beam 111a, column 111b, cross bar 111c, inclined bar 111d, top roof truss 111e; wall 112, rolling shutter door 112a; roof 113, fiberglass lighting strip 113a; truss car system 120; hoisting truss car 121; truss car track 122; truss car beam 123; corbel 124; walking system 130; guide rail 131; Device 134b, coupling 134c; control room 140; ladder 141; inner gutter 150; rainwater pipe 160;

Intelligent monitoring platform 200; Intelligent monitoring equipment 210; Global Eye 211; Capture device 212; Aerial camera 213; Environmental detector 214; Data server 220; Intelligent terminal 230; Base station 240;

Intelligent sprinkler system 300; water storage tank 310; high-pressure water pump 320; liquid delivery pipe 330; flexible pipe 340; slide rail 341; spray pipe 350; nozzle 351; microprocessor 360; 362; clock controller 363; humidity detector 370.

detailed description

The integral self-propelled fully enclosed green construction fence provided by the utility model will be further described in detail below in conjunction with the accompanying drawings and specific embodiments. The advantages and features of the present utility model will be more clear in conjunction with the following description and claims. It should be noted that all the drawings are in very simplified form and use inaccurate scales, which are only used to facilitate and clearly illustrate the purpose of the embodiment of the present utility model.

Embodiment one

Please refer to Fig. 1 to Fig. 5, wherein Fig. 1 is the cross-sectional view of the integral self-propelled fully enclosed green construction enclosure provided by the present embodiment, Fig. 2 is the front view of the construction enclosure, Fig. 3 is the side view of the construction enclosure, Fig. 4 Sectional view of the corbel and truss car track; Figure 5 is a schematic structural diagram of the walking system. Below in conjunction with Fig. 1 to Fig. 5, the overall self-propelled fully enclosed green construction fence provided by the utility model is further described.

The integral self-propelled fully enclosed green construction fence 100 provided by the utility model includes a main structure 110 , a truss vehicle system 120 and a walking system 130 . The main structure 110 includes a main frame 111 , a wall 112 arranged around the main frame 111 and a roof 113 arranged on the top of the main frame. The wall 112 and the roof 113 form a closed space. 1 and 2, the walls 112 at both ends of the construction enclosure 100 are provided with rolling doors 112a. When the construction enclosure moves as a whole, the rolling doors 112a are rolled up so as not to damage the equipment parked in the construction area or the piled materials. make an impact.

As shown in Figure 1 and Figure 3, the main frame 111 includes two bottom beams 111a located on both sides of the construction area and arranged in parallel, several columns 111b fixed on the bottom beams 111a, cross bars 111c arranged between the columns 111b and The inclined rod 111d, the top roof truss 111e arranged above the column 111b and spanning the construction area, as shown in Figure 1, the bottom beam 111a, the column 111b and the top roof truss 111e form a structurally stable portal frame.

As shown in FIG. 1 and FIG. 4 , the girder car system 120 includes a hoisting girder truck 121 across the construction area, a girder truck track 122 located at both ends of the hoisting girder truck 121 , a girder truck girder 123 located below the girder truck rail 122 and The corbel 124 arranged on the column 111b, the truss beam 123 is fixedly arranged on the corbel 124, and arranged parallel to the bottom beam 111a. The lifting girder truck 121 can move forward and backward along the girder truck rail 122 , and the electric hoist can move left and right along the girder truck beam, so that the working area of the electric hoist can cover the entire construction enclosure 100 .

As shown in Figure 1 and Figure 5, the walking system 130 includes guide rails 131 arranged on the foundations on both sides of the construction area, guide wheels 132 arranged below the bottom beam 111a, a driving device 133 arranged on the main frame 111, and a connecting drive The gear 134 of the device 133 and the guide wheel 132 . The guide wheel 132 rests on the guide rail 131, and the driving device 133 can be a motor disposed between the upright post 111b and the bottom beam 111a. Preferably, the transmission device 134 includes a brake wheel coupling 134 a , a reducer 134 b , and a shaft coupling 134 c connected in sequence, the brake wheel coupling 134 c is connected to the driving device 133 , and the shaft coupling 134 c is connected to the guide wheel 132 . The working principle of the walking system is: after the motor is energized, electromagnetic torque is generated, which is transmitted to the reducer 134b through the brake wheel coupling 134a, and after gear transmission deceleration, the output shaft drives the guide wheel 132 along the guide rail 131 through the coupling 134c The top surface slides, so that the construction enclosure 100 moves forward or backward as a whole.

The operating mechanism of the guide wheel 132 can be divided into two forms: centralized drive and separate drive. The centralized drive is driven by a motor through the drive shaft to drive the guide wheels 132 on both sides of the construction enclosure 100, and the separate drive is driven by two or more motors. Drive the guide wheels 132 on both sides of the construction enclosure 100 respectively. Because the volume of construction fence 100 is big, and length is longer, it is bound to select the mode of multi-wheel drive. Preferably, a control room 140 is provided on the main body frame 111 , equipped with a drive platform that coordinates multiple wheels to rotate at the same speed at the same time, and a ladder 141 is provided to facilitate the operator to enter the control room 140 .

As an example, the wall 112 is made of double-layer laminated steel plates for thermal insulation. From outside to inside, they are: outer color steel plate, rock wool roll felt, heat-insulating reflective aluminum foil, structural steel purlin and inner color steel plate. As an example, the color steel plate with a thickness of 0.4mm and model YX35-125-750 can be used for the outer color steel plate, the thickness of the rock wool roll felt is 50mm, the thickness of the heat-insulating reflective aluminum foil is 0.2mm, and the thickness of the inner color steel plate is 0.4mm , Model YX15-225-900 color steel plate. The wall body 112 provided in this embodiment has the advantages of durability, heat preservation, and noise reduction.

As an example, the roof 113 is a composite roof with double-layer daylighting boards, and the order from top to bottom is: profiled steel plate, rock wool roll felt, paper-based reinforced aluminum foil veneer, stainless steel wire mesh and profiled steel purlin. As an example, the profiled steel plate with a thickness of 0.4mm and model YX51-380-760 can be used, the thickness of the rock wool roll felt can be 60mm, the thickness of the paper-based reinforced aluminum foil veneer is 0.2mm, and the profiled steel purlin can be used Galvanized cold-formed steel additional purlins. In this embodiment, the paper-based reinforced aluminum foil veneer can isolate water vapor, the steel purlins increase the overall stability of the roof 113, the rock wool felt makes the roof 113 have heat preservation and noise prevention functions, and the stainless steel wire mesh prevents the rock wool felt from The paper base reinforced foil veneer was torn. Therefore, the roof 113 provided in this embodiment has the functions of heat preservation and noise reduction, and at the same time has a reasonable structure and good mechanical properties.

In order to increase the lighting performance of the roof, it is preferable to set a plurality of strip-shaped or block-shaped FRP lighting strips 113a on the roof 113 at intervals. As an example, the FRP lighting strips 113a can adopt double-layer flame-retardant FRP lighting strips 113a, and the light transmittance is ≥ 80 %, oxygen index ≥ 30%. Preferably, the FRP lighting belt 113a has a melting point of 100°C-200°C, and will melt when exposed to fire or high temperature. In case of fire, the lighting belt melts and becomes a smoke exhaust channel, further ensuring the safety of personnel in the construction area. In order to further ensure the lighting rate of the roof, while satisfying structural stability and facilitating rainwater discharge, it is preferable that the roof 113 adopts a triangular arch shape, and a resin lighting board is arranged at the ridge, and the two ends of the resin lighting board are overlapped and fixed on the roofs on both sides . As an example, the resin daylighting board can adopt a double-layer corrugated resin daylighting board.

As shown in FIG. 1 , the upper edge of the wall 112 is higher than the lower edge of the roof 113 , there is a certain distance between the wall 112 and the roof 113 , and an inner gutter 150 is arranged between them to collect rainwater. For drainage of rainwater, the inner gutter 150 is connected with a rainwater pipe 160 , and the lower end of the rainwater pipe 160 protrudes outside the wall 112 . As an example, the inner gutter 150 can adopt a galvanized steel plate with a thickness of 4mm, and brush the polyurethane anti-corrosion coating, and fill the joint between the inner gutter 150 and the rainwater pipe 160 with sealant to prevent side leakage of rainwater; the rainwater pipe 160 adopts a diameter of 110mm PVC pipes shall be installed every 12m. For further discharge of rainwater, a drain can be set directly below the nozzle of the rainwater pipe 160 lower end.

A preferred embodiment is that an unpowered hood is arranged above the roof 113 to convert the air flow parallel to the roof to the air flow vertically, so as to improve the indoor ventilation effect. The non-powered hood has the advantages of no energy consumption, no noise, and long-term operation, and can discharge indoor hot air and dirty air to improve the indoor environment; when there is horizontal wind on the roof, it can be introduced into the construction enclosure 100 to provide fresh air .

The utility model adopts a fully enclosed construction enclosure 100, and a walking system 130 is arranged below the bottom crossbeam 111a of the construction enclosure 100, so that the construction enclosure 100 has the following advantages or beneficial effects: (1) The fully enclosed environment can Isolate noise, dust, and bright light to create a better surrounding environment for construction and reduce the impact on residents; (2) The fully enclosed environment can prevent the impact of extreme weather such as rain, snow, and wind on construction, and can also ensure the construction at night Continuity of construction, shortening the construction period to the greatest extent; (3) By carrying the walking system 130, the fully enclosed construction enclosure 100 can be moved freely along the subway construction line, and can be easily moved from one construction bid section to another The bidding section avoids repeated installation and dismantling work, which not only saves a lot of time and cost, but also keeps up with the fast-paced subway construction, and maximizes the scope of application and coverage of fully enclosed construction enclosures.

Embodiment two

Please refer to Figure 6, which is a block diagram of the connection relationship of the intelligent monitoring platform. The intelligent monitoring platform 200 of the construction enclosure 100 will be further described below with reference to FIGS. 1 to 6 .

The smart monitoring platform 200 includes a smart monitoring device 210 , a data server 220 for receiving and storing monitoring data of the smart monitoring device 210 , and a smart terminal 230 for displaying the monitoring data and controlling the smart monitoring device 210 . Among them, the intelligent detection equipment 210 can be: a global eye 211 arranged on the main frame 111 and the lifting truss truck 121, a capture device 212 for capturing vehicles entering and exiting the rolling door 112a, and an aerial camera 213 for monitoring the construction area, And an environmental detector 214 for monitoring data such as air temperature and humidity, particulate matter content, and noise in the construction enclosure 100 . Wherein, the data server 220 can receive the monitoring data from the intelligent monitoring device 210 and store it, and perform corresponding processing on the stored data, such as comparing with a preset threshold value to determine whether the particle content therein exceeds the standard. Wherein, the smart terminal 230 may be a desktop computer, a notebook computer, a tablet computer, a smart phone, or a dedicated smart device. Among them, the intelligent monitoring device 210, the data server 220 and the intelligent terminal 230 can be connected in a wired or wireless manner.

By arranging an intelligent monitoring platform in the construction enclosure 100, the utility model has the following advantages or beneficial effects: the intelligent detection platform 200 can be installed to monitor the humidity, temperature, noise, solid particle concentration, and in-and-out vehicles in the construction enclosure 100. , construction scenes, etc., real-time control of the construction information within the construction enclosure 100, and even monitoring information such as foundation pit deformation, pressurized water level, etc.

Preferably, the data server 220 is also connected to the base station 240 , and the monitoring data or data processing results in the data server are sent to the remote intelligent terminal 250 through the base station 240 . The remote intelligent terminal 250 can be a desktop computer, a notebook computer, a tablet computer, a smart phone, or a dedicated smart device.

Embodiment three

Please refer to FIG. 7 . FIG. 7 is a schematic structural diagram of the intelligent sprinkler system provided in this embodiment. The intelligent sprinkler system will be further described below in conjunction with FIG. 1 and FIG. 7 .

The construction enclosure 100 is provided with an intelligent sprinkler system 300, wherein the intelligent sprinkler system 300 includes a water storage tank 310, a high-pressure water pump 320, a liquid delivery pipe 330, a flexible pipe 340 and a spray pipe 350 connected in sequence, and also includes a support for the The slide rail 341 of the flexible pipe 340 is suspended on the top roof truss 111e, the spray pipe 350 is suspended on the hoisting truss truck 121, and a plurality of nozzles 351 are arranged at intervals on the spray pipe 350.

The high-pressure water pump 320 is also connected with a microprocessor 360, and the microprocessor 360 includes a water pump on-off switch 361 for controlling the high-pressure water pump to be turned on and off, and a water pump speed controller 362 for controlling the speed of the high-pressure water pump. As an example, an on-off circuit of the high-pressure water pump 320 is provided on the microprocessor 360 as a water pump on-off switch 361 for controlling the high-pressure water pump 320 . The water pump rotational speed controller 362 controls its rotational speed by changing the current or voltage acting on the high pressure water pump 320 , or controls its rotational speed by changing the transmission ratio of the transmission shaft gear of the high pressure water pump 320 . The change of the rotation speed of the high-pressure water pump 320 directly affects the water pressure in the spray pipe 350 , thereby changing the atomized spray intensity of the nozzle 351 .

The intelligent sprinkler system 300 is also provided with a humidity detector 370 , which is electrically connected to the microprocessor 360 for monitoring the air humidity at the working surface of the construction area, and transmits the monitoring data to the microprocessor 360 . According to the monitored air humidity data, the speed of the high-pressure water pump 320 can be changed, thereby controlling the atomization and spraying intensity of the spray pipe 350, and always maintaining the air humidity within a certain range. The humidity detector 370 can be hung on the lifting truss truck 121, and can also be set in the foundation pit at the construction surface.

Preferably, the microprocessor 360 is provided with a clock controller 363, which can control the working mode of the high-pressure water pump 320, so as to realize timing spraying or intermittent automatic spraying of the spray pipe 350. As an example, the clock controller 363 can be set to automatically close the water pump on-off switch 361 every 20 minutes, so that the spray pipe 350 can perform spraying operations. After the spray pipe 350 sprays for 10 minutes, the clock controller 363 is automatically disconnected. The water pump turns on and off the switch 361 to stop the spraying operation of the spraying pipe 350, thereby realizing the intermittent spraying of the spraying pipe 350, thereby reducing water consumption while achieving a better dust removal effect.

This embodiment has the following advantages or beneficial effects: (1) The spray pipe 350 is fixed on the hoisting truss truck 121, and the hoisting truss truck 121 is usually located directly above the work surface in the construction area, and the spray pipe 350 can be installed with the hoisting truss Car 121 moves and effectively sprays the dust source all the time; (2) the flexible pipe 340 fixed on the slide rail 341 can automatically expand and contract with the movement of the spray pipe 350, satisfying the demand of the dynamic change of the spray pipe 350; (3 ) The microprocessor 360 intelligently controls the opening and closing of the high-pressure water pump 320 according to the air humidity data monitored by the humidity detector 370 , thereby intelligently controlling the air humidity in the construction enclosure 100 .

The intelligent sprinkler system 300 provided in this embodiment can be called a movable intelligent sprinkler system 300. Compared with the traditional fixed sprinkler system, the movable intelligent sprinkler system 300 requires fewer spray pipes 350, Easy to install; and the spray pipe 350 of the movable intelligent spray system 300 always sprays the dust source on the working surface of the construction area, the spray effect is good, and water resources are saved; in addition, the spray pipe 350 can be used with the hoist The car 121 moves to realize the full coverage spraying of the construction area.

Embodiment four

Please refer to FIG. 8 . FIG. 8 is a flow chart of the construction method of the fully enclosed green construction enclosure provided in this embodiment. Below in conjunction with Fig. 1 to Fig. 8, the construction method of the construction enclosure will be further described. The construction method of construction fence 100 specifically comprises the following steps:

S1. Install the construction fence 100, and conduct all-round inspection and debugging on the construction fence 100. Install guide rail 131, guide wheel 132, main frame 111 first, then install truss vehicle system 120, and finally install wall 112, roof 113, driving device 133, transmission device 134, intelligent monitoring platform 200, intelligent sprinkler system 300 and rainwater pipes 160 etc. The inspection and debugging specifically include the following contents: retest the deviation between the guide rail 131 and the guide wheel 132, the levelness of the guide rail 131, and the distance between two parallel guide rails 131; mark the uneven settlement on the column 111b to facilitate long-term re-inspection in the future Uneven settlement; debug the engine, debug the control platform in the control room 140, and check whether the engines can be driven in concert; test the performance of the hoisting truss truck 121 when the construction enclosure 100 is stopped. After each installation or movement is completed, the above inspection and debugging needs to be carried out to ensure the usability and safety performance of the construction fence 100 .

S2. Carry out construction on the construction section, and when the construction section is completed, lock the hoisting truss truck 121, then start the driving device 133, drive the guide wheel 132 to roll along the guide rail 131, and move the construction enclosure 100 to the The next construction section. After the first installation, the construction fence 100 is located above the section to be constructed, and is prevented from moving. During normal construction, it is necessary to control all engines to stop, and control the speed reducer 134b to lock the guide wheel 132. Only in this way can the hoisting truss truck 121 be used to carry out operations such as soil fetching, horizontal and vertical transportation. After the construction of the construction section is completed, when the construction fence 100 is to be moved to another construction area, the hoisting truss truck 121 can be parked directly above a certain corbel 124 and then locked. After the guide rail 132 is correct, Open the double-opening shutter doors 112a on the east and west sides of the construction enclosure 100 to avoid collisions with objects during the movement. In the control room 150, the limit of the reducer 134b is released, and the engine moves to the designated position in coordination.

S3. Turn off the driving device 133, lock the guide wheel 132 on the guide rail 131, and proceed to the construction work of the next construction section.

S4. Steps S2-S3 are repeated until all construction sections are completed, and then the construction enclosure 100 is removed. When dismantling, first control the reducer 134b to limit the movement of the guide wheel 132 . Ancillary facilities that do not affect the main structure, such as walls 112, roofs 113, intelligent monitoring equipment 210, intelligent sprinkler system 300, etc., are removed. The truss truck system 120 is dismantled by a crane, and then the main frame 111 and the walking system 130 are dismantled until the dismantling is completed.

The above description is only a description of the preferred embodiments of the present utility model, and is not any limitation to the scope of the present utility model. Any changes and modifications made by those of ordinary skill in the field of the utility model according to the above disclosures all belong to the protection scope of the claims .

Claims (9)

1. a kind of totally-enclosed green construction enclosing of whole self-propelled formula, it is characterised in that the construction guard fender includes：

Agent structure, including main body framework, be arranged at the wall of the main body framework surrounding and be arranged at the main body framework top The roofing in portion, the wall and the roofing enclose closing space；The main body framework is included positioned at construction area both sides simultaneously The base cross members that be arranged in parallel, some columns being fixed in the base cross members, the cross bar being arranged between the column and Brace, it is arranged above the column and across the top roof truss of the construction area；Institute corresponding to the base cross members both ends State and rolling screen door is provided with wall；

Purlin car system, including lift heavy purlin car across the construction area, positioned at purlin track road, the position at the lift heavy purlin car both ends Purlin bicycle beam below the purlin track road and the bracket being arranged on the column, the purlin bicycle beam are fixedly installed on the ox On leg；

Running gear, including be arranged on the ground of construction area both sides guide rail, be arranged at below the base cross members guide wheel, The drive device being arranged in the main body framework, and connect the transmission device of the drive device and the guide wheel.

2. construction guard fender as claimed in claim 1, it is characterised in that the transmission device includes the braked wheel connection being sequentially connected Axle device, decelerator, shaft coupling, the braked wheel shaft coupling are connected with the drive device, and the shaft coupling connects with the guide wheel Connect.

3. construction guard fender as claimed in claim 2, it is characterised in that the construction guard fender also includes OPS, the manipulation Room is arranged in the main body framework, is connected by cat ladder with ground.

4. construction guard fender as claimed in claim 1, it is characterised in that the construction guard fender also includes intellectual monitoring platform, institute Stating intellectual monitoring platform includes Intelligent monitoring device, is taken for receiving and storing the data of the Intelligent monitoring device Monitoring Data Business device, and for showing Monitoring Data and manipulating the intelligent terminal of the Intelligent monitoring device.

5. construction guard fender as claimed in claim 4, it is characterised in that the Intelligent monitoring device comprises at least following one：

Global eyes, the global eyes be arranged in the main body framework and/or lift heavy purlin car on；

Instrument is captured, door described in the candid photograph instrument face is set；

Aerial photography device, the aerial photography device are arranged in the construction guard fender；

Environment detector, the environment detector are arranged in lift heavy purlin car and/or main body framework.

6. construction guard fender as claimed in claim 1, it is characterised in that intelligent spray system is additionally provided with the construction guard fender System, the Intelligent spraying system include storage tank, high-pressure hydraulic pump, liquid pushing tube, flexible pipe and the shower being sequentially connected, in addition to The slide rail of the flexible pipe is supported, the slide rail is suspended on the top roof truss, and the shower is suspended on the lift heavy purlin Che Shang, multiple nozzles are arranged at intervals with the shower；The high-pressure hydraulic pump is connected with microprocessor, the miniature processing Device includes the water pump open-close on-off for controlling the high-pressure hydraulic pump to open and close and the pump rotary speed control for controlling the high-pressure hydraulic pump rotating speed Device；The microprocessor is also associated with humidity measurement instrument.

7. construction guard fender as claimed in claim 1, it is characterised in that multiple strips or block glass are arranged at intervals on the roofing Glass steel ribbon skylight.

8. construction guard fender as claimed in claim 7, it is characterised in that the fiberglass ribbon skylight fusing point is 100 DEG C~200 ℃。

9. construction guard fender as claimed in claim 1, it is characterised in that along the lower edge for being higher by the roofing, institute on the wall State and interior gutter is provided between wall and roofing, the interior gutter connects with storm sewer upper end, the lower end of the storm sewer Stretch out the wall.