CN216339633U - Rapid construction precipitation device - Google Patents

Abstract

The utility model provides a rapid construction dewatering device which comprises a driving gear, wherein the outer side of the driving gear is connected with a driven gear in a meshed mode, the inner wall of the driven gear is connected with a driving shaft in a threaded mode, a cap sleeving pipe is arranged at the bottom of the driving shaft, a connecting block is arranged at the bottom of the cap sleeving pipe, a rotating block is arranged at the bottom of the connecting block, a non-porous sleeve is arranged at the bottom of the rotating block, and a porous sleeve is arranged at the bottom of the non-porous sleeve. The rapid construction dewatering device provided by the utility model solves the problems that the service life of a reinforced concrete structure is greatly reduced due to the fact that underground water has weak corrosivity on the reinforced concrete structure in the process of earth excavation and the construction quality is influenced due to the fact that the underground water level rises and water is reversed from a post-cast strip of the structure, unnecessary economic loss is caused, and serious social influence is caused.

Description

Rapid construction precipitation device

Technical Field

The utility model relates to the technical field of construction equipment, in particular to a rapid construction dewatering device.

Background

The construction is a production activity in the construction implementation stage of the engineering construction, which is a construction process of various buildings, or a process of changing various lines on a design drawing into a real object at a designated place, and comprises basic engineering construction, main structure construction, roofing engineering construction, decoration engineering construction and the like, wherein the place of construction operation is called a construction site or a construction site, the construction operation is a production activity for constructing various building products in a certain space and time by using various building materials and mechanical equipment according to a specific design blueprint, and comprises all production processes from construction preparation, earth breaking activity to engineering completion acceptance, wherein the production processes comprise construction preparation, construction organization design and management, earthwork, blasting engineering, foundation engineering, steel bar engineering, construction and management, earth construction and building, and construction engineering, construction work, and management, construction work, and decoration work, and the like, The construction method comprises the following working operations of template engineering, scaffold engineering, concrete engineering, prestressed concrete engineering, masonry engineering, steel structure engineering, wood structure engineering, structure installation engineering and the like.

At present, along with the increase of high-rise buildings in the construction industry, precipitation is frequently encountered in the earthwork excavation process, and sometimes, underground water has weak corrosivity on a reinforced concrete structure, so that the service life of the reinforced concrete structure is greatly reduced, and meanwhile, the rising of the underground water level can cause water return from a post-structure casting area, so that not only is the construction quality influenced, but also unnecessary economic loss is caused, and serious social influence is caused.

Therefore, there is a need to provide a new rapid construction precipitation device to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problems, the utility model provides the rapid construction dewatering device which is simple in design, convenient to use and capable of improving the construction quality.

The utility model provides a rapid construction dewatering device which comprises a driving gear, wherein a driven gear is connected to the outer side of the driving gear in a meshed mode, a driving shaft is connected to the inner wall of the driven gear in a threaded mode, a cap sleeve is arranged at the bottom of the driving shaft, a connecting block is arranged at the bottom of the cap sleeve, a rotating block is arranged at the bottom of the connecting block, a non-porous sleeve is arranged at the bottom of the rotating block, a porous sleeve is arranged at the bottom of the non-porous sleeve, a spiral sleeve is arranged at the bottom of the porous sleeve, a flow pump is arranged in an inner cavity of the spiral sleeve, a water pumping end of the flow pump is communicated with a liquid level sensor through a water inlet pipe, and a water outlet pipe is communicated with a water outlet end of the flow pump.

In order to achieve the effect of improving the drilling efficiency, the utility model provides a rapid construction precipitation device, preferably, the top of the liquid level sensor is communicated with a first pipeline, and one side of the rotating block is provided with a water suction pump.

In order to achieve the effect of water drainage, the utility model provides a rapid construction precipitation device, preferably, the water drainage end of the water suction pump is communicated with a water drainage pipe, the water pumping end of the water suction pump is communicated with a second pipeline, and the outer sides of the first pipeline and the second pipeline are both connected with a fixed seat in a sliding manner.

In order to achieve the effect of convenient installation and disassembly, the utility model provides a rapid construction dewatering device, preferably, threaded rods are fixedly connected to the bottoms of the driving shaft, the cap sleeving pipe, the non-porous sleeve and the porous sleeve, and threaded holes matched with the threaded rods are formed in the tops of the cap sleeving pipe, the connecting block, the porous sleeve and the spiral sleeve.

In order to achieve the effect of facilitating installation of the first pipeline and the second pipeline, the utility model provides the rapid construction precipitation device, preferably, the bottom of the connecting block is fixedly connected with a rotating rod, the outer side of the rotating rod is rotatably connected with the inner wall of a rotating block, a first through hole matched with the first pipeline and the second pipeline for use is formed in the outer side of the rotating block, and a second through hole matched with the first pipeline and the second pipeline for use is formed in the top of the non-porous sleeve.

In order to achieve the protection effect, the utility model provides a rapid construction precipitation device, preferably, the outer sides of the perforated sleeve and the spiral sleeve are both provided with third through holes, and the inner wall of each third through hole is provided with a filter screen.

In order to achieve the effect of driving the liquid level sensor to operate, the utility model provides a rapid construction precipitation device.

In order to achieve the effect of convenient control, preferably, one side of the host is electrically connected with the liquid level sensor through a signal line, the top of the host is provided with a display, and the front surface of the display is provided with a control panel.

Compared with the prior art, the utility model has the beneficial effects that:

the rapid construction dewatering device is characterized in that the outer side of a driving gear is meshed and connected with a driven gear, the inner wall of the driven gear is in threaded connection with a driving shaft, so that the driving shaft rotates, the driving shaft is in threaded connection with a sleeve pipe through a threaded rod, the sleeve pipe is in threaded connection with a connecting block through a threaded rod, the connecting block is fixedly connected with a non-porous sleeve through a rotating rod, the inner wall of the rotating block is in rotational connection with the outer side of the rotating rod, when the connecting block and the non-porous sleeve rotate, the rotating block keeps a relatively static state, the first pipeline and the second pipeline are prevented from being wound, the bottom of the non-porous sleeve is in threaded connection with the porous sleeve through the threaded rod, the bottom of the porous sleeve is in threaded connection with a spiral sleeve through the threaded rod, the threaded rod is used for fixing the whole sleeve, the convenience is brought for installing and disassembling the whole sleeve, the convenience is greatly improved, and meanwhile, the sleeve below is driven to spirally drill soil through the rotation of the driving shaft, the driving shaft can rotate and drill, the whole sleeve is driven to enter soil downwards in the forward rotation process, the whole sleeve is driven to withdraw soil upwards in the reverse rotation process, a flow pump is arranged in an inner cavity of the spiral sleeve and is communicated with a liquid level sensor through a water inlet pipe, the top of the liquid level sensor is communicated with a first pipeline, the flow pump pumps water into the spiral sleeve through the first pipeline, after passing through the liquid level sensor, the change of liquid level and time is recorded through the liquid level sensor, the water depth and the fed water quantity in different periods can be recorded, then the water is discharged through a water outlet pipe, the effect of conveying the spiral sleeve is achieved, the downward drilling is easier, the drilling efficiency is greatly improved, a water pumping end of the water pumping pump is communicated with a second pipeline through the arrangement of the water pumping pump, one end of the second pipeline extends to the inner cavity of the spiral sleeve, and therefore underground water is pumped out through the water pumping pump, the drainage pipe discharges water, so that the aim of rapid precipitation is fulfilled, and the problems that the service life of a reinforced concrete structure is greatly shortened due to the fact that existing high-rise buildings are increased frequently along with the increase of building industry, precipitation is frequently encountered in the earth excavation process, and sometimes, underground water is slightly corrosive to the reinforced concrete structure, and meanwhile, the water is reversed from a post-cast strip of the structure due to the rise of underground water level, so that not only is the construction quality influenced, but also unnecessary economic loss is caused, and serious social influence is caused are solved.

Drawings

FIG. 1 is a schematic structural view of a preferred embodiment of a rapid construction precipitation apparatus according to the present invention;

FIG. 2 is a schematic view of the connection of the imperforate sleeve and the perforate sleeve of FIG. 1;

FIG. 3 is a schematic view of the first and second conduits of FIG. 1;

FIG. 4 is a schematic view of the rotating block shown in FIG. 1;

FIG. 5 is a schematic view showing an internal structure of the spiral casing shown in FIG. 1;

fig. 6 is a schematic view of the connection of the driving gear and the driven gear shown in fig. 1.

Reference numbers in the figures: 1. a driving gear; 2. a driven gear; 3. a drive shaft; 4. sleeving a cap pipe; 5. connecting blocks; 6. rotating the block; 7. a non-porous sleeve; 8. a perforated sleeve; 9. a spiral sleeve; 10. a flow pump; 11. a water inlet pipe; 12. a liquid level sensor; 13. a water outlet pipe; 14. a first conduit; 15. a water pump; 16. a drain pipe; 17. a second conduit; 18. a fixed seat; 19. a threaded rod; 20. a threaded hole; 21. a rotating rod; 22. a first through hole; 23. a second through hole; 24. a third through hole; 25. filtering with a screen; 26. a crawler body; 27. a host; 28. a display; 29. a control panel.

Detailed Description

The utility model is further described with reference to the following figures and embodiments.

Referring to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5 and fig. 6, fig. 1 is a schematic structural diagram of a rapid construction precipitation apparatus according to a preferred embodiment of the present invention; FIG. 2 is a schematic view of the connection of the imperforate sleeve and the perforate sleeve of FIG. 1; FIG. 3 is a schematic view of the first and second conduits of FIG. 1; FIG. 4 is a schematic view of the rotating block shown in FIG. 1; FIG. 5 is a schematic view showing an internal structure of the spiral casing shown in FIG. 1; fig. 6 is a schematic view of the connection of the driving gear and the driven gear shown in fig. 1. A rapid construction precipitation device comprises a driving gear 1.

In the specific implementation process, as shown in fig. 1, fig. 2, fig. 3, fig. 4, fig. 5 and fig. 6, the driven gear 2 is engaged and connected to the outer side of the driving gear 1, the driving shaft 3 is connected to the inner wall of the driven gear 2 in a threaded manner, the cap pipe 4 is arranged at the bottom of the driving shaft 3, the connecting block 5 is arranged at the bottom of the cap pipe 4, the rotating block 6 is arranged at the bottom of the connecting block 5, the non-porous sleeve 7 is arranged at the bottom of the rotating block 6, the porous sleeve 8 is arranged at the bottom of the non-porous sleeve 7, the spiral sleeve 9 is arranged at the bottom of the porous sleeve 8, the flow pump 10 is arranged in the inner cavity of the spiral sleeve 9, the water pumping end of the flow pump 10 is communicated with the liquid level sensor 12 through the water inlet pipe 11, and the water discharging end of the flow pump 10 is communicated with the water outlet pipe 13.

Referring to fig. 1, 3 and 5, the top of the liquid level sensor 12 is communicated with a first pipeline 14, and a water suction pump 15 is arranged on one side of the rotating block 6.

Referring to fig. 1, 3 and 5, a drainage end of the water pump 15 is communicated with a drainage pipe 16, a pumping end of the water pump 15 is communicated with a second pipeline 17, and the outer sides of the first pipeline 14 and the second pipeline 17 are both connected with a fixed seat 18 in a sliding manner.

Referring to fig. 1, 2, 3 and 4, threaded rods 19 are fixedly connected to the bottoms of the driving shaft 3, the cap sleeving pipe 4, the non-porous casing pipe 7 and the porous casing pipe 8, and threaded holes 20 matched with the threaded rods 19 for use are formed in the tops of the cap sleeving pipe 4, the connecting block 5, the porous casing pipe 8 and the spiral casing pipe 9.

Referring to fig. 1, 2, 3, 4 and 5, a rotating rod 21 is fixedly connected to the bottom of the connecting block 5, the outer side of the rotating rod 21 is rotatably connected to the inner wall of the rotating block 6, a first through hole 22 matched with the first pipeline 14 and the second pipeline 17 for use is formed in the outer side of the rotating block 6, and a second through hole 23 matched with the first pipeline 14 and the second pipeline 17 for use is formed in the top of the imperforate casing 7.

It should be noted that: the outer side of the driving gear 1 is engaged with a driven gear 2, the inner wall of the driven gear 2 is in threaded connection with a driving shaft 3, so that the driving shaft 3 rotates, the driving shaft 3 is in threaded connection with a cap pipe 4 through a threaded rod 19, the cap pipe 4 is in threaded connection with a connecting block 5 through the threaded rod 19, the connecting block 5 is fixedly connected with a non-porous sleeve 7 through a rotating rod 21, the inner wall of the rotating block 6 is in rotational connection with the outer side of the rotating rod 21, when the connecting block 5 and the non-porous sleeve 7 rotate, the rotating block 6 keeps a relatively static state, the first pipeline 14 and the second pipeline 17 are prevented from being wound, the bottom of the non-porous sleeve 7 is in threaded connection with a porous sleeve 8 through the threaded rod 19, the bottom of the porous sleeve 8 is in threaded connection with a spiral sleeve 9 through the threaded rod 19 and is fixed through the threaded rod 19, the whole sleeve is convenient to install and disassemble, and the convenience is greatly improved, meanwhile, the driving shaft 3 rotates to drive the lower sleeve to drill into soil spirally, the driving shaft 3 can rotate while drilling, the whole sleeve is driven to enter soil downwards in forward rotation, the whole sleeve is driven to withdraw from soil upwards in reverse rotation, a flow pump 10 is arranged in the inner cavity of the spiral sleeve 9, the flow pump 10 is communicated with a liquid level sensor 12 through a water inlet pipe 11, the top of the liquid level sensor 12 is communicated with a first pipeline 14, the flow pump 10 pumps water into the soil through the first pipeline 14, after passing through the liquid level sensor 12, the change of liquid level and time is recorded through the liquid level sensor 12, the water depth and the supplied water quantity in different time periods can be recorded, and then the water is discharged through a water outlet pipe 13, so that the effect of delivering water to the spiral sleeve 9 is achieved, the downward drilling is easier, the drilling efficiency is greatly improved, and by arranging a water suction pump 15, the pumping end of the water pump 15 is communicated with a second pipeline 17, one end of the second pipeline 17 extends to the inner cavity of the spiral sleeve 9, therefore, the water pump 15 pumps the underground water out, the water is discharged through the water discharge pipe 16, and the purpose of rapid precipitation is achieved.

Referring to fig. 1, 2 and 5, third through holes 24 are formed on the outer sides of the perforated sleeve 8 and the spiral sleeve 9, and a filter screen 25 is arranged on the inner wall of each third through hole 24.

Referring to fig. 6, a crawler body 26 is provided outside the drive shaft 3, and a main body 27 is provided on the top of the crawler body 26.

Referring to fig. 6, one side of the main unit 27 is electrically connected to the liquid level sensor 12 through a signal line, a display 28 is disposed on the top of the main unit 27, and a control panel 29 is disposed on the front surface of the display 28.

It should be noted that: third through hole 24 has all been seted up in the outside of porose sleeve pipe 8 and spiral sleeve pipe 9, make things convenient for the entering and the discharge of water, and filter screen 25 prevents effectively that sand and soil from getting into porose sleeve pipe 8 and spiral sleeve pipe 9's inside, the top of tracked vehicle body 26 is provided with the diesel engine, drive driving gear 1 and rotate as power take off through the diesel engine, the top of tracked vehicle body 26 is provided with host computer 27, host computer 27 provides power output for level sensor 12 through the signal line, level sensor 12 will detect the different periods the depth of water and feed water volume transmission to display 28 on, control panel 29 is used for controlling and adjusts, made things convenient for the staff to operate.

The working principle of the rapid construction dewatering device provided by the utility model is as follows:

before use, the crawler body 26 is moved to a precipitation place, a diesel engine is arranged at the top of the crawler body 26, the driving gear 1 is driven to rotate by taking the diesel engine as power output, the outer side of the driving gear 1 is engaged and connected with a driven gear 2, the inner wall of the driven gear 2 is in threaded connection with a driving shaft 3, so that the driving shaft 3 rotates, the driving shaft 3 is in threaded connection with a cap sleeve 4 through a threaded rod 19, the cap sleeve 4 is in threaded connection with a connecting block 5 through the threaded rod 19, the connecting block 5 is fixedly connected with a non-porous sleeve 7 through a rotating rod 21, the inner wall of a rotating block 6 is in threaded connection with the outer side of the rotating rod 21, when the connecting block 5 and the non-porous sleeve 7 rotate, the rotating block 6 keeps a relative static state, the first pipeline 14 and the second pipeline 17 are prevented from being wound, and the bottom of the non-porous sleeve 7 is in threaded connection with the porous sleeve 8 through the threaded rod 19, the bottom of the sleeve 8 with the hole is in threaded connection with the spiral sleeve 9 through the threaded rod 19 and is fixed through the threaded rod 19, so that the whole sleeve can be conveniently installed and detached, the convenience is greatly improved, meanwhile, the sleeve below is driven to drill soil spirally through the rotation of the driving shaft 3, the driving shaft 3 can drill while rotating, the whole sleeve is driven to enter the soil downwards when rotating forwards, the whole sleeve is driven to withdraw from the soil upwards when rotating backwards, meanwhile, the flow pump 10 is arranged in the inner cavity of the spiral sleeve 9, the flow pump 10 is communicated with the liquid level sensor 12 through the water inlet pipe 11, the top of the liquid level sensor 12 is communicated with the first pipeline 14, the flow pump 10 pumps water into the liquid level sensor 12 through the first pipeline 14, after passing through the liquid level sensor 12, the host 27 provides electric power output for the liquid level sensor 12 through a signal line, the liquid level sensor 12 transmits the detected water depth and the detected water supply quantity in different time intervals to the display 28, control panel 29 is used for controlling and adjusting, discharge through outlet pipe 13 after that, thereby reached and sent the effect of water to spiral sleeve 9, it is easier when making to creep into downwards, the efficiency of creeping into is greatly improved, through setting up suction pump 15, the end intercommunication that draws water of suction pump 15 has second pipeline 17, the one end of second pipeline 17 extends to spiral sleeve 9's inner chamber, thereby take groundwater out through suction pump 15, and discharge through drain pipe 16, thereby the purpose of quick precipitation has been reached.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (8)

1. The rapid construction precipitation device is characterized by comprising a driving gear (1), wherein the driving gear (1) is meshed with a driven gear (2), the inner wall of the driven gear (2) is in threaded connection with a driving shaft (3), a cap sleeve (4) is arranged at the bottom of the driving shaft (3), a connecting block (5) is arranged at the bottom of the cap sleeve (4), a rotating block (6) is arranged at the bottom of the connecting block (5), a non-porous sleeve (7) is arranged at the bottom of the rotating block (6), a porous sleeve (8) is arranged at the bottom of the non-porous sleeve (7), a spiral sleeve (9) is arranged at the bottom of the porous sleeve (8), a flow pump (10) is arranged in an inner cavity of the spiral sleeve (9), and the water pumping end of the flow pump (10) is communicated with a liquid level sensor (12) through a water inlet pipe (11), the water discharge end of the flow pump (10) is communicated with a water outlet pipe (13).

2. The rapid construction precipitation device according to claim 1, characterized in that a first pipeline (14) is communicated with the top of the liquid level sensor (12), and a water pump (15) is arranged on one side of the rotating block (6).

3. The rapid construction precipitation device according to claim 2, wherein the water discharge end of the water suction pump (15) is communicated with a water discharge pipe (16), the water suction end of the water suction pump (15) is communicated with a second pipeline (17), and the outer sides of the first pipeline (14) and the second pipeline (17) are both connected with a fixed seat (18) in a sliding manner.

4. The rapid construction precipitation device according to claim 1, wherein threaded rods (19) are fixedly connected to the bottoms of the driving shaft (3), the cap sleeve (4), the non-porous sleeve (7) and the porous sleeve (8), and threaded holes (20) matched with the threaded rods (19) are formed in the tops of the cap sleeve (4), the connecting block (5), the porous sleeve (8) and the spiral sleeve (9).

5. The rapid construction precipitation device according to claim 1, wherein a rotating rod (21) is fixedly connected to the bottom of the connecting block (5), the outer side of the rotating rod (21) is rotatably connected to the inner wall of the rotating block (6), a first through hole (22) matched with the first pipeline (14) and the second pipeline (17) for use is formed in the outer side of the rotating block (6), and a second through hole (23) matched with the first pipeline (14) and the second pipeline (17) for use is formed in the top of the non-porous casing (7).

6. The rapid construction precipitation device according to claim 1, wherein the outer sides of the perforated sleeve (8) and the spiral sleeve (9) are provided with third through holes (24), and the inner wall of the third through holes (24) is provided with a filter screen (25).

7. The rapid construction precipitation device according to claim 1, characterized in that a crawler body (26) is arranged outside the driving shaft (3), and a main machine (27) is arranged on the top of the crawler body (26).

8. The rapid construction precipitation device according to claim 7, wherein one side of the main machine (27) is electrically connected with the liquid level sensor (12) through a signal line, a display (28) is arranged on the top of the main machine (27), and a control panel (29) is arranged on the front surface of the display (28).

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