CN217870827U - Intelligent building site dewatering and drainage system - Google Patents

Abstract

The utility model discloses an intelligent construction site dewatering and drainage system, which comprises a floating bridge structure and a support structure arranged on the floating bridge structure, wherein a control box is arranged on the support structure, a main control panel is arranged in the control box, and a 380v Schneider contactor, a 220v Schneider contactor, a signal transmitter and a 4G network IO controller are sequentially arranged on the main control panel from left to right; the lower row of the main control panel is provided with a 380v air switch and a 220v air switch from left to right in sequence; the 380v Schneider contactor, the 220v Schneider contactor and the signal transmitter are connected with the 4G network IO controller; the 380v air switch and the 220v air switch are respectively connected with a 380v Schneider contactor and a 220v Schneider contactor. The utility model discloses can real-time supervision water level, in time overrun report to the police, arouse the water pump automatically and deal with the water level emergency, carry out intelligent building site and fall the drainage.

Description

Intelligent building site dewatering and drainage system

Technical Field

The utility model relates to a building engineering field, concretely relates to intelligent building site dewatering and drainage system.

Background

The accumulated water of the existing construction site is usually accumulated in a foundation pit dewatering well and a basement low-lying platform of the construction site, and the accumulated water mainly comprises foundation pit soil body water seepage, rainfall accumulated water and construction water. Extraction and discharge are usually required, otherwise construction hidden danger and quality problems are easily caused. The ponding in current building site depression or the foundation ditch precipitation well is measured, is usually by artifical untimely measurement, then manual opening the drain pump according to the condition, falls the drainage. To the daily monitoring of job site water level, traditional equipment is inefficient, consuming time, the cost of labor is high, when meetting rainy night emergency, the job site personnel of being not convenient for in time deal with, at ordinary times more can't master in real time and judge the regional water yield water level condition of construction, all leave the hidden danger for the job site, consequently need an intelligent building site to fall drainage system, can the real-time supervision water level, in time overrun reports to the police, automatic arouse the water pump and deal with water level emergency, carry out the drainage that falls in intelligent building site.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem that prior art exists, the utility model aims to provide an intelligent building site drainage system that falls can real-time supervision water level, in time overrun report to the police, automatic arouse the water pump to deal with the water level emergency, carries out intelligent building site drainage that falls.

In order to further realize the above purpose, the utility model adopts the following technical scheme:

an intelligent construction site dewatering and drainage system comprises a floating bridge structure and a support structure arranged on the floating bridge structure, wherein a control box is arranged on the support structure,

a main control panel is arranged in the control box, and a 380v Schneider contactor, a 220v Schneider contactor, a signal transmitter and a 4G network IO controller are sequentially arranged on the main control panel from left to right;

the main control panel is provided with a 380v air switch and a 220v air switch from left to right in sequence from the lower row;

the 380v Schneider contactor, the 220v Schneider contactor and the signal transmitter are connected with a 4G network IO controller;

the 380v air switch and the 220v air switch are respectively connected with a 380v Schneider contactor and a 220v Schneider contactor.

Optionally, the floating bridge structure includes a heterotypic floating bridge piece that sets up between two parties and centers on heterotypic floating bridge piece is around and rather than a plurality of floating bridge pieces of concatenation, circular through-hole has been seted up between two parties to heterotypic floating bridge piece, circular through-hole internal fixation has the pvc pipe.

Furthermore, the support structure comprises two horizontal alloy frames arranged in parallel and two vertical alloy frames arranged in parallel, the horizontal alloy frames are arranged on the special-shaped floating bridge blocks, and the vertical alloy frames are vertically arranged on the horizontal alloy frames to form the groined support structure.

Furthermore, two transverse winch mounting frames are arranged at the upper ends of the middle parts of the two vertical alloy frames; an electric hoist is arranged above the winch mounting frame; the lifting hook part of the electric hoist is used for being connected with a water pump lifting seat, and the water pump lifting seat is installed on the water pump.

Optionally, four corners of the bottom of the control box are provided with box supporting feet, the bottom of each box supporting foot is provided with a box mounting plate, and the box mounting plates are mounted on the vertical alloy frame through the mounting supporting feet.

Optionally, a top cover is arranged at the top of the control box, a handle is arranged in the middle of the top cover, and an antenna is arranged on one side of the top cover; the front end of the control box is provided with a front cover which can be opened and closed, and one side of the front cover is provided with a front door lock.

Optionally, a power supply is further arranged below the main control panel, and the power supply is connected with the 4G network IO controller and the signal transmitter to supply power to the 4G network IO controller and the signal transmitter.

Compared with the prior art, the beneficial effects of the utility model are as follows:

1. simple structure, the component original paper is the commercially available part of five metals, and the cost is lower.

2. Carry out integrated combination with each controller control panel in the control box, accessible 4G network IO controller transmits the internet, both can set for the alarm value and carry out intelligent control water pump drainage of drawing water, also can show water level data in real time at the cell-phone end for constructor can in time monitor foundation ditch water level data.

3. Accessible signal transmitter inserts mechanisms such as pore water pressure probe, and through placing pore water pressure probe in the soil bottom, measurable quantity goes out soil top water pressure, is the floater measurement water level usually in comparison with prior art, can't show real-time water level data, the utility model discloses still can show soil top water pressure data in real time, make water level data obtain in time monitoring, and compare in traditional water pressure measurement, this measuring mechanism measuring range is wider, and the measurement in places such as the pipeline of installation is not convenient for like the floater, all can well deal with.

4. Through the cross pontoon structure that four pontoon blocks and a heterotypic pontoon block concatenation formed, the groined type bearing structure that two sets of vertical alloy framves in cooperation top and horizontal alloy frame are constituteed, when the building site water level rose, the pontoon block can in time float, and the stability of mechanisms such as upper portion control box can be guaranteed again to the structure that the alloy frame of top was constituteed simultaneously, prevents that the device is whole to intake.

5. Through heterotypic pontoon bridge piece middle part open-ended design for water pump accessible electric block directly hangs into environments such as foundation ditch precipitation well inside, still can hoist whole system through the tower crane and remove to the place of needs and monitor, has effectively enlarged this intelligent building site and has fallen drainage system's application scene.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the application and together with the description serve to explain the application and not to limit the application. In the drawings:

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the structure of the special-shaped floating bridge block of the present invention;

fig. 3 is a logic block diagram of the connection of each device on the main control panel of the present invention.

Description of reference numerals:

1-a control box; 2-a top cover; 3-a front cover; 4-an antenna; 5-a handle; 6-front door lock; 7-a main control panel; 8-a power supply; 9-220v blank; 10-380v open; 11-380v schneider contactor; 12-220v schneider contactor; 13-a signal transmitter; 14-4G network IO controllers; 15-box body support legs; 16-a tank mounting plate; 17-mounting feet; 18-a vertical alloy frame; 19-a transverse alloy frame; 20-a floating bridge block; 21-a winch mounting; 22-electric hoist; 23-special-shaped floating bridge blocks; 24-pvc tubing; 25-a water pump; 26-water pump lifting seat.

Detailed Description

To facilitate understanding and implementation of the present invention for those skilled in the art, the following detailed description of the present invention is provided in connection with the accompanying drawings and the implementation examples, and it is to be understood that the implementation examples described herein are only used for illustration and explanation of the present invention and are not used for limiting the present invention.

An intelligent construction site water lowering and draining system is shown in figures 1 and 2 and comprises a floating bridge structure, a transverse alloy frame 19 and a vertical alloy frame 18 which are sequentially arranged on the floating bridge structure, and a control box 1 arranged on the vertical alloy frame 18, wherein box body support legs 15 are arranged at four corners of the bottom of the control box 1, and the bottoms of the box body support legs 15 are fixedly arranged on a box body mounting plate 16 below the box body support legs; the box body mounting plate 16 is fixedly mounted on a lower vertical alloy frame 18 through mounting support legs 17; the two vertical alloy frames 18 are arranged in parallel in the left-right direction and are combined and installed with the two transverse alloy frames 19 arranged in parallel in the front-back direction to form a support structure in a # -shape, so that the whole structure is more stable.

The floating bridge structure is formed by splicing a special-shaped floating bridge block 23 and a plurality of floating bridge blocks 20. The special-shaped floating bridge blocks 23 and the floating bridge blocks 20 can adopt buoys of type 50 x 40 produced by Hubei Conn engineering Limited company, and an upper device is supported on the water surface through buoyancy; the utility model discloses explain for example four pontoon bridge piece 20 and heterotypic pontoon bridge piece 23, heterotypic pontoon bridge piece 23 is placed between two parties, and four pontoon bridge piece 20 are located heterotypic pontoon bridge piece 23 four sides respectively, form crisscross pontoon bridge structure after assembling. The crisscross floating bridge structure formed by splicing the four floating bridge blocks 20 and the special-shaped floating bridge block 23 is matched with the support structure in the shape of a Chinese character jing formed by the two vertical alloy frames 18 and the transverse alloy frame 19 above, when the water level of a construction site rises, the floating bridge blocks can float in time, and meanwhile, the support structure formed by the alloy frames above can ensure the stability of mechanisms such as the upper control box 1 and the like, so that the whole device is prevented from entering water. Or the floating bridge blocks can be spliced according to the actual site requirement, such as forming a complete rectangle and the like, so as to ensure the stability of the upper device.

Two transverse winch mounting frames 21 are fixedly mounted above the inside of the groined support structure formed by the vertical alloy frames 18 and the transverse alloy frames 19, namely the upper ends of the middles of the two vertical alloy frames 18; an electric hoist 22 is fixedly arranged above the winch mounting frame 21; the electric hoist 22 is a PA200 micro electric hoist of Shanghai Stand and erect Crane Co., ltd, can be remotely controlled by accessing the 4G network IO controller 14, and further lifts the lower water pump 25 to be deep under the foundation pit dewatering well; the vertical alloy frame 18 and the horizontal alloy frame 19 form a groined lower part in the support structure, namely a special-shaped floating bridge block 23 is fixedly installed in the middle of the bottoms of the two horizontal alloy frames 19, a circular through hole is formed in the middle of the special-shaped floating bridge block 23, a pvc pipe 24 with a slightly smaller diameter and a slightly longer length than the circular through hole is inserted, colloid is filled between the pvc pipe 24 and the circular through hole for fixing, through the design of the pvc pipe and the middle opening, a water pump 25 and a water level sensor can penetrate into a foundation pit dewatering well through a channel formed by the circular through hole, and the buoyancy loss of the special-shaped floating bridge block 23 caused by the middle opening can be minimized; the water pump 25 can be placed into the foundation pit dewatering well through a passage formed by circular through holes in the special-shaped floating bridge blocks 23, the position of the water pump is always positioned in the passage, a water pump hoisting seat 26 is installed on the water pump hoisting seat, and the water pump hoisting seat 26 can be connected with the lifting hook part of the electric hoist 22 for hoisting; the water level sensor (not shown in the figure) should be hung into the foundation pit dewatering well together with the water pump 25, that is, the water level measured by the water level sensor is always the same as the actual water level of the water pump 25, so as to ensure the accuracy of pumping water.

The top of the control box 1 is provided with a top cover 2, the middle part of the top cover 2 is provided with a handle 5, and one side of the top cover 2 is provided with an antenna 4, wherein the antenna 4 is an auxiliary part of a 4G network IO controller 14, when the whole control box 1 needs to be moved, the whole control box can be moved by directly lifting the handle 5, or when the control box 1 needs to be hoisted, the handle 5 can be hung below a tower crane to move; the front end of the control box 1 is provided with a front cover 3 which can be opened and closed, and one side of the front cover 3 is provided with a front door lock 6 which is used for opening and closing the control box 1 and preventing the external environment from interfering the interior of the box body.

As shown in fig. 1 and 3, a main control panel 7 is arranged in a control box 1, the main control panel 7 is vertically fixed in the control box 1, and a 380v schneider contactor 11, a 220v schneider contactor 12, a signal transmitter 13 and a 4G network IO controller 14 are sequentially arranged on the main control panel 7 from left to right; the main control panel 7 is provided with a 380v air switch 10, a 220v air switch 9 and a power supply 8 from left to right in sequence from the lower row; the 380v Schneider contactor 11, the 220v Schneider contactor 12 and the signal transmitter 13 are connected with the 4G network IO controller 14; the 380v Schneider contactor 11 can be connected with a 380v power supply to supply power to a 380v water pump, and the 220v Schneider contactor 12 can be connected with a 220v power supply to supply power to a 220v water pump; namely, the 380v schneider contactor 11 and the 220v schneider contactor 12 can be applied to water pumps with different powers, such as 380v schneider contactor and 220v schneider contactor, respectively, so as to meet different drainage requirements; the 380v air switch 10 is connected with a 380v Schneider contactor 11 and is used for overload protection of the contactor; the 220v air switch 9 is connected with a 220v Schneider contactor 12 and is used for overload protection of the contactor; the power supply 8 is connected with the 4G network IO controller 14, the signal transmitter 13, the pore water pressure probe and the water level sensor and supplies power to the 4G network IO controller 14, the signal transmitter 13, the pore water pressure probe and the water level sensor.

The signal transmitter 13 is connected with a pore water pressure probe (not shown in the figure), and by placing the pore water pressure probe at the bottom of the soil, the strain of the soil above the pore water pressure probe can be converted into a current value to be transmitted to the 4G network IO controller 14, so that the water level above the soil can be measured; or the 4G network IO controller 14 can be connected with a water level sensor arranged at the bottom of the foundation pit dewatering well; the 4G network IO controller 14 can upload the current value of the sensor to an Internet of things cloud platform through a 4G wireless network, the water level value can be accurately obtained on the Internet of things cloud platform through mapping transformation, a monitoring function is achieved, a proper trigger condition is selected on a trigger of the Internet of things cloud platform, when the monitored water level exceeds a water level limit value, an alarm value set by the Internet of things cloud platform transmits an instruction to the 4G network IO controller 14, the instruction is transmitted to a Schneider contactor by the Schneider contactor, closing of the Schneider contactor is automatically controlled, the water pump is controlled to be started to pump water, when the water level is lower than the limit value, the Schneider contactor is opened, the water pump is closed, the operation can be actively controlled through a mobile terminal, the mobile terminal mainly logs in the Internet of things cloud platform through a mobile phone public number to operate a control panel, the Schneider contactor is manually controlled to be closed and opened, or water level data are monitored in real time; and the Internet of things cloud platform can be directly logged in through a computer terminal to carry out remote control.

It should be noted that, the above-mentioned controller is the commonality, can purchase in the five metals market, wherein:

380v Schneider contactor 11 is type LC1D32Q7C of Schneider electric company Limited;

the 220v schrader contactor 12 is model LC1D32M7C from schrader electric limited;

the signal transmitter 13 is WJ15 type of Shenzhen Weijunrui science and technology Limited;

the 4G network IO controller 14 is a ZHC492C type of Chengdu intelligent control technology company Limited;

the pore water pressure probe is DMKY type of Nanjing Dan strange electronic technology Co., ltd;

the water level sensor is HC-L300TP type of Huacheng measuring and controlling equipment of Qingdao.

It should be understood that the above description of the preferred embodiments is given in some detail, and not as a limitation to the scope of the invention, and that various alternatives and modifications can be devised by those skilled in the art without departing from the scope of the invention as defined by the appended claims.

Claims (7)

1. An intelligent construction site water lowering and draining system comprises a floating bridge structure and a support structure arranged on the floating bridge structure, and is characterized in that a control box (1) is arranged on the support structure,

a main control panel (7) is arranged in the control box (1), and a 380v Schneider contactor (11), a 220v Schneider contactor (12), a signal transmitter (13) and a 4G network IO controller (14) are sequentially arranged on the main control panel (7) from left to right;

the main control panel (7) is provided with a 380v air switch (10) and a 220v air switch (9) from left to right in sequence;

the 380v Schneider contactor (11), the 220v Schneider contactor (12) and the signal transmitter (13) are connected with a 4G network IO controller (14);

the 380v air switch (10) and the 220v air switch (9) are respectively connected with a 380v Schneider contactor (11) and a 220v Schneider contactor (12).

2. The intelligent construction site water lowering and draining system according to claim 1, wherein the floating bridge structure comprises a special-shaped floating bridge block (23) arranged in the middle and a plurality of floating bridge blocks (20) which surround and are spliced with the special-shaped floating bridge block (23), a circular through hole is formed in the middle of the special-shaped floating bridge block (23), and a pvc pipe (24) is fixed in the circular through hole.

3. The intelligent construction site water lowering and draining system according to claim 2, wherein the support structure comprises two parallel-arranged transverse alloy frames (19) and two parallel-arranged vertical alloy frames (18), the transverse alloy frames (19) are mounted on the special-shaped floating bridge blocks (23), and the vertical alloy frames (18) are vertically mounted on the transverse alloy frames (19) to form a well-shaped support structure.

4. The intelligent construction site dewatering and drainage system according to claim 3, wherein two transverse winch mounting frames (21) are mounted at the upper ends of the middles of the two vertical alloy frames (18); an electric hoist (22) is arranged above the winch mounting rack (21); the lifting hook part of electric block (22) is used for connecting water pump lifting seat (26), install on water pump (25) water pump lifting seat (26).

5. The intelligent construction site water lowering and draining system according to claim 1, wherein four corners of the bottom of the control box (1) are provided with box body support legs (15), a box body mounting plate (16) is mounted at the bottom of each box body support leg (15), and the box body mounting plate (16) is mounted on a vertical alloy frame (18) through mounting support legs (17).

6. The intelligent construction site water lowering and draining system according to claim 1, wherein a top cover (2) is arranged at the top of the control box (1), a lifting handle (5) is arranged in the middle of the top cover (2), and an antenna (4) is arranged on one side of the top cover; the front end of the control box (1) is provided with a front cover (3) which can be opened and closed, and one side of the front cover (3) is provided with a front door lock (6).

7. The intelligent construction site water lowering and draining system according to claim 1, wherein a power supply (8) is further arranged below the main control panel (7), and the power supply (8) is connected with the 4G network IO controller (14) and the signal transmitter (13) to supply power to the IO controller.

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