CN113857168A - Pier steel protects a high pressure washing unit - Google Patents

Abstract

The invention relates to a high-pressure washing device for a steel pile casing of a pier, which effectively solves the problem of reduced smoothness caused by cleaning the inner wall of the steel pile casing; the technical scheme for solving the problem is that the pipeline comprises a transverse first pipeline, wherein the left end of the first pipeline is sealed, and a connecting sleeve is fixed at the right end of the first pipeline; a second pipeline capable of moving left and right along the connecting sleeve is arranged in the connecting sleeve; a rubber plug is arranged at the left end of the second pipeline, and a pressure spring positioned at the right end of the rubber plug and the connecting sleeve is sleeved on the second pipeline; the right end of the second pipeline is provided with a rotary spray head; a plurality of telescopic supporting legs are arranged on the first pipeline and the second pipeline; the outer ends of the telescopic supporting legs are provided with rollers; wherein the rollers on the telescopic supporting legs on the first pipeline can only rotate in one direction; two detection devices are arranged on the second pipeline, and the detection devices can control the first pipeline or the second pipeline to be communicated with water; the invention is suitable for pipelines with various lengths and diameters and can be flexibly used.

Description

Pier steel protects a high pressure washing unit

Technical Field

The invention relates to the field of bridge construction, in particular to a high-pressure washing device for a pier steel casing.

Background

In the process of bridge construction, before the cast-in-situ bored pile is constructed, a steel casing is usually required to be installed at an orifice, so that the soil body at the orifice is effectively prevented from collapsing into the hole. When the construction of the overwater bored pile is carried out, particularly in the construction of a pile foundation of a bridge across the river and the sea, the steel casing needs to be sunk to a stable stratum from the overwater, and the steel casing not only has the function of preventing the soil body at the orifice from collapsing, but also has the functions of template, reinforcement and the like. Then concrete is required to be poured in the steel casing, and the steel casing can be pulled out after the concrete is poured; the smoothness of the inner wall of the steel casing directly influences the difficulty of pulling out. After the steel casing is pulled out, the steel casing needs to be cleaned and maintained in time to prevent concrete from being attached to the upper part.

The traditional cleaning method mostly adopts a steel brush for cleaning, and although the efficiency of the steel brush is high, the smoothness of the inner wall of the steel casing can be directly influenced; the inner wall of the steel casing is well protected by cleaning with a high-pressure water gun, but the steel casing is long and inconvenient to clean; and for some concrete blocks that have already set; the water gun is difficult to wash; still need the manual work to scrape alone, reduced efficiency, increased the cost of labor. There is therefore a need for a more convenient way to operate.

Disclosure of Invention

In view of the above situation, the present invention provides a high pressure washing apparatus for pier steel casing, which can effectively solve the problem of smoothness reduction during cleaning the inner wall of the steel casing.

The technical scheme for solving the problem is that the pipeline comprises a transverse first pipeline, wherein the left end of the first pipeline is sealed, and a connecting sleeve is fixed at the right end of the first pipeline; a second pipeline capable of moving left and right along the connecting sleeve is arranged in the connecting sleeve; a rubber plug is arranged at the left end of the second pipeline, and a pressure spring positioned at the right end of the rubber plug and the connecting sleeve is sleeved on the second pipeline; the right end of the second pipeline is provided with a rotary spray head; a plurality of telescopic supporting legs are arranged on the first pipeline and the second pipeline; the outer ends of the telescopic supporting legs are provided with rollers; wherein the rollers on the telescopic supporting legs on the first pipeline can only rotate in one direction;

two detection devices are arranged on the second pipeline, and each detection device comprises a sleeve capable of moving left and right; a plurality of supporting rods are arranged on the outer edge surface of the sleeve in a stepping mode, arc-shaped scraping plates are hinged to the end portions of the supporting rods, and torsion springs are arranged at the hinged points;

the first pipeline and the second pipeline are respectively connected with a first water inlet pipe and a second water inlet pipe; the first water inlet pipe and the second water inlet pipe are respectively controlled by a first valve and a second valve; the two valves are respectively in one-to-one correspondence with the two detection devices; after the detection device moves leftwards, the valve rod of the corresponding valve can be extruded, the state of the valve is switched, and then water flows into the first pipeline.

The first pipeline is provided with an overflow port, and the diameter of the overflow port is smaller than that of the first water inlet pipe.

The rotary spray head comprises a straight pipe which is arranged at the right end of the second pipeline and can rotate; the right end of the straight pipe is arranged on the outer side of the second pipeline and is provided with a plurality of vertical nozzles, and the left end of the straight pipe is arranged in the second pipeline and is provided with an impeller.

The outer aid face of gyro wheel be provided with the rubber layer, be located the gyro wheel on every flexible landing leg on the first pipeline and all install one way clutch, when flexible landing leg removed from a left side to the right side, the gyro wheel can rotate.

The first valve and the second valve are both two-position three-way valves, and each valve comprises a valve body, wherein an upper inlet, a left outlet and a right outlet are formed in the valve body; a plug is arranged at the central position of the valve body, and an inverted T-shaped channel is arranged in the plug; the lower end of the plug is connected with a valve rod, and a pressure spring is sleeved on the valve rod.

The upper inlet of the first valve is connected with a water source; the right outlet of the first valve is connected with the upper inlet of the second valve; the left outlet of the first valve is connected with the first water inlet pipe; the right outlet of the second valve is connected with a second pipeline; the left outlet of the second valve is connected with the first water inlet pipe.

The detection device comprises a fixed block fixed on the second pipeline, the fixed block and the sleeve are respectively connected with a connecting rod, the free ends of the two connecting rods are hinged together, and the common hinge point of the two connecting rods is positioned under the valve rod; the first valve and the second valve are respectively fixed on the supporting rods of the two detection devices.

The first water inlet pipe and the second water inlet pipe are hoses.

The invention has the advantages that:

1. the water gun is used for rotating to shoot, so that the cleaning without dead angles is comprehensively realized, and the inner wall is protected.

2. The quick water pressure in conventional region is cleared up, to the concrete block region, can carry out the operation of shovel automatically.

3. The power of rivers is utilized, has realized quick clearance and the linkage and the drive between the shovel, and both automatic switch cooperate ingeniously.

4. The pipeline is suitable for pipelines with various lengths and diameters and can be flexibly reused.

5. The sewage after cleaning can be automatically discharged, thereby avoiding remaining and causing rusting.

Drawings

Fig. 1 is a front sectional view i (working state) of the present invention.

FIG. 2 is a front sectional view II (horizontally disposed) of the present invention.

Fig. 3 is a partially enlarged view of a portion shown in fig. 2 according to the present invention.

FIG. 4 is a perspective view of a detecting part in the present invention.

Fig. 5 is a front sectional view (state one) of two valves in cooperation.

Fig. 6 is a front sectional view of two valves in cooperation (state two).

Detailed Description

The following describes in further detail embodiments of the present invention with reference to the accompanying drawings.

As shown in fig. 1 to 6, the present invention includes a transverse first pipeline 1, the left end of the first pipeline 1 is sealed, and the right end is fixed with a connecting sleeve 2; a second pipeline 3 which can move left and right along the connecting sleeve 2 is arranged in the connecting sleeve 2; a rubber plug 4 is arranged at the left end of the second pipeline 3, and a pressure spring positioned at the rubber plug 4 and the right end of the connecting sleeve 2 is sleeved on the second pipeline 3; the right end of the second pipeline 3 is provided with a rotary nozzle 5; a plurality of telescopic supporting legs 6 are arranged on the first pipeline 1 and the second pipeline 3; the outer end of the telescopic supporting leg 6 is provided with a roller 7; wherein the rollers 7 on the telescopic supporting legs 6 positioned on the first pipeline 1 can only rotate in one direction;

two detection devices 10 are arranged on the second pipeline 3, and each detection device 10 comprises a sleeve 1001 capable of moving left and right; a plurality of supporting rods 1002 are arranged on the outer edge surface of the sleeve 1001 in a stepping mode, arc-shaped scrapers 1003 are hinged to the end portions of the supporting rods 1002, and torsion springs are arranged at the hinged points;

the first pipeline 1 and the second pipeline 3 are respectively connected with a first water inlet pipe 11 and a second water inlet pipe 12; the first inlet pipe 11 and the second inlet pipe 12 are controlled by a first valve 13 and a second valve 14 respectively; the two valves are respectively in one-to-one correspondence with the two detection devices 10; when the detecting device 10 moves to the left, it can press the valve stem 1307 of the corresponding valve to switch the state of the valve, and then make water flow into the first pipe 1.

In order to facilitate the resetting of the second pipe 3, the first pipe 1 is provided with an overflow port 15, and the diameter of the overflow port 15 is smaller than that of the first water inlet pipe 11.

In order to realize rotation, the rotary spray head 5 comprises a straight pipe which is arranged at the right end of the second pipeline 3 and can rotate; the right end of the straight pipe is arranged on the outer side of the second pipeline 3 and is provided with a plurality of vertical nozzles, and the left end of the straight pipe is arranged in the second pipeline 3 and is provided with an impeller.

In order to improve the friction force, a rubber layer is arranged on the outer surface of the roller 7, a one-way clutch 8 is mounted on the roller 7 on each telescopic supporting leg 6 on the first pipeline 1, and when the telescopic supporting legs 6 move from left to right, the rollers 7 can rotate.

In order to realize the state switching of the valve after the valve rod 1307 of the valve moves upwards, the first valve 13 and the second valve 14 are both two-position three-way valves, and each three-way valve comprises a valve body 1301, wherein an upper inlet 1302, a left outlet 1303 and a right outlet 1304 are arranged on the valve body 1301; a plug 1305 is arranged at the central position of the valve body 1301, and an inverted T-shaped channel 1306 is arranged in the plug 1305; the lower end of the plug 1305 is connected with a valve rod 1307, and the valve rod 1307 is sleeved with a pressure spring.

In order to realize the control of water flow, the upper inlet 1302 of the first valve 13 is connected with a water source; the right outlet 1304 of the first valve 13 is connected to the upper inlet 1302 of the second valve 14; the left outlet 1303 of the first valve 13 is connected with the first water inlet pipe 11; the right outlet 1304 of the second valve 14 is connected with the second pipeline 3; the left outlet 1303 of the second valve 14 is connected to the first inlet pipe 11.

In order to realize the extrusion of the valve, the detection device 10 comprises a fixed block 1004 fixed on the second pipeline 3, a connecting rod 1005 is connected with the fixed block 1004 and the sleeve 1001, the free ends of the two connecting rods are hinged together, and the common hinge point of the two connecting rods is positioned right below the valve rod 1307; the first valve 13 and the second valve 14 are respectively fixed on the support rods 1002 of the two detection devices 10.

In order to realize the movement, the first water inlet pipe and the second water inlet pipe are both hoses.

When the telescopic supporting leg device is used, firstly, the telescopic supporting leg 6 can be stretched, and the compression spring is arranged on the telescopic supporting leg 6, so that the telescopic supporting leg 6 can be stretched outwards, and the whole device can be plugged into the steel casing after the telescopic supporting leg 6 is pressed before use; referring to figures 1 and 2; in this state, the arc squeegee 1003 is in contact with the inner wall of the steel casing.

After the whole device is put in, a water source switch is turned on, and the left end of the steel casing is lifted; at the moment, the steel casing is inclined, so that the whole device can automatically and slowly move rightwards along the steel casing under the action of self weight.

See fig. 2 and 5; in a default state, the high-pressure water flows into the upper inlet 1302 of the second valve 14 through the upper inlet 1302 of the first valve 13, and then flows into the second channel 1306 through the second inlet pipe 12; the left end of the second channel 1306 is sealed by the rubber plug 4; therefore, water flow can flow out from the right end of the second pipeline 3, and through the design of the rotary spray head 5, the water flow can impact the impeller, so that the straight pipe on the rotary spray head 5 rotates and then is sprayed out from a nozzle at the right end of the straight pipe; the nozzle can spray and rotate along with the nozzle, so that the inner wall of the steel casing can be flushed in all directions.

The flushed sewage and sundries can flow out of the pipeline rightwards along the inner wall of the steel casing.

The left and right detection devices 10 are positioned at the left side of the nozzle, so that the inner wall of the steel casing is basically kept clean after the nozzle is cleaned, and if small particles are encountered, the small particles are directly cleaned by the arc-shaped scraper 1003. If large concrete blocks are encountered; the concrete block will block the detection device 10 from moving to the right; through two detection device 10, make two detection device 10's branch 1002 staggered arrangement, can realize the all-round detection to steel casing inner wall, no matter which position has the concrete piece, the homoenergetic blocks one of them detection device 10.

After the detection device 10 is blocked, the whole device continues to slide rightwards for a short distance under the action of self weight; the detection device 10 is now moved to the left with respect to the second duct 3; the hinge configuration of the two struts 1002 between the sleeve 1001 and the fixed block 1004 on the detection device 10 is changed, see fig. 3, and at this time, the common hinge point of the two connecting rods 1005 presses the valve rod 1307 upwards; the state of the valve is changed. The specific changes are as follows:

when the valve rod 1307 of the right second valve 14 is pressed, the water flows into the second valve 14 through the first valve 13, then flows into the first water inlet pipe 11 through the left outlet 1303 of the second valve 14, and then enters the first pipeline 1; the same process is carried out; when the valve stem 1307 of the left first valve 13 is pressed upwards, the water flows directly into the first pipe 1 from the left outlet 1303 of the first valve 13.

Because the roller 7 on the telescopic supporting leg 6 on the first pipeline 1 can only rotate in a single direction, the first pipeline 1 can only move from left to right along the inner wall of the steel casing under the action of the roller 7 in the mode, and the second pipeline 3 is not influenced and can move forwards or backwards.

When water flows into the first pipeline 1, the pressure in the first pipeline 1 is increased by the water flow; since the first pipe 1 cannot move leftward, the water pressure will move the second pipe 3 in the connecting sleeve 2 rightward; when the second pipeline 3 moves rightwards, the detection device 10 is driven to move rightwards together, so that the arc-shaped scraper 1003 also moves rightwards, and the impact of the arc-shaped scraper 1003 on the concrete block is realized by utilizing the impact force. When the arc plate passes over the concrete block, the arc scraper 1003 is not blocked, and the valve rod 1307 is reset downwards; then the arc plate will move right again relative to the second conduit 3 (by pressing the common hinge point of the two links 1005 when the valve stem 1307 is reset down), then the common hinge point of the two links 1005 is not pressing the valve stem 1307; the valve stem 1307 is reset downwards; the water flow flows into the first pipe 1 again to perform the jet cleaning.

The first pipe 1 is provided with the overflow port 15, and the second pipe 3 is slowly restored after the overflow port 15 slowly drains water. Because the diameter of the overflow port is small, when the first pipeline is filled with water, a part of water pressure is released, but the whole operation is not influenced.

When in actual use, the water source can be controlled to be switched on and off according to the requirement, so that multiple times of impact can be performed, and a better effect can be realized.

Claims (8)

1. A pier steel casing high-pressure flushing device comprises a transverse first pipeline (1), and is characterized in that the left end of the first pipeline (1) is sealed, and a connecting sleeve (2) is fixed at the right end of the first pipeline (1); a second pipeline (3) capable of moving left and right along the connecting sleeve (2) is arranged in the connecting sleeve (2); a rubber plug (4) is arranged at the left end of the second pipeline (3), and a pressure spring positioned at the rubber plug (4) and the right end of the connecting sleeve (2) is sleeved on the second pipeline (3); the right end of the second pipeline (3) is provided with a rotary spray head (5); a plurality of telescopic supporting legs (6) are respectively arranged on the first pipeline (1) and the second pipeline (3); the outer end of the telescopic supporting leg (6) is provided with a roller (7); wherein the rollers (7) on the telescopic supporting legs (6) positioned on the first pipeline (1) can only rotate in one direction;

two detection devices (10) are mounted on the second pipeline (3), and each detection device (10) comprises a sleeve (1001) capable of moving left and right; a plurality of supporting rods (1002) are arranged on the outer edge surface of the sleeve (1001) in a stepping mode, arc-shaped scrapers (1003) are hinged to the end portions of the supporting rods (1002), and torsion springs are arranged at the hinged points;

the first pipeline (1) and the second pipeline (3) are respectively connected with a first water inlet pipe (11) and a second water inlet pipe (12); the first water inlet pipe (11) and the second water inlet pipe (12) are respectively controlled by a first valve (13) and a second valve (14); the two valves are respectively in one-to-one correspondence with the two detection devices (10); after the detection device (10) moves leftwards, the valve rod (1307) of the corresponding valve can be pressed to switch the state of the valve, and then water flows into the first pipeline (1).

2. The pier steel casing high-pressure flushing device according to claim 1, wherein a spillway gap (15) is formed in the first pipeline (1), and the diameter of the spillway gap (15) is smaller than that of the first water inlet pipe (11).

3. The pier steel casing high-pressure flushing device according to claim 1, wherein the rotary nozzle (5) comprises a straight pipe which is arranged at the right end of the second pipeline (3) and can rotate; the right end of the straight pipe is arranged on the outer side of the second pipeline (3) and is provided with a plurality of vertical nozzles, and the left end of the straight pipe is arranged in the second pipeline (3) and is provided with an impeller.

4. The pier steel casing high-pressure flushing device according to claim 1, wherein a rubber layer is arranged on the outer surface of the roller (7), a one-way clutch (8) is mounted on the roller (7) on each telescopic leg (6) on the first pipeline (1), and the roller (7) can rotate when the telescopic legs (6) move from left to right.

5. The pier steel casing high-pressure flushing device according to claim 1, wherein the first valve (13) and the second valve (14) are both two-position three-way valves, and each three-way valve comprises a valve body (1301), wherein an upper inlet (1302), a left outlet (1303) and a right outlet (1304) are arranged on the valve body (1301); a plug (1305) is arranged at the central position of the valve body (1301), and an inverted T-shaped channel (1306) is arranged inside the plug (1305); the lower end of the plug (1305) is connected with a valve rod (1307), and a pressure spring is sleeved on the valve rod (1307).

6. The pier steel casing high-pressure flushing device as claimed in claim 1, wherein the upper inlet (1302) of the first valve (13) is connected with a water source; the right outlet (1304) of the first valve (13) is connected with the upper inlet (1302) of the second valve (14); the left outlet (1303) of the first valve (13) is connected with the first water inlet pipe (11); the right outlet (1304) of the second valve (14) is connected with the second pipeline (3); the left outlet (1303) of the second valve (14) is connected with the first water inlet pipe (11).

7. The pier steel casing high-pressure washing device according to claim 1, wherein the detection device (10) comprises a fixed block (1004) fixed on the second pipeline (3), a connecting rod (1005) is connected with the fixed block (1004) and the sleeve (1001) in a connecting mode, the free ends of the two connecting rods (1005) are hinged together, and the common hinge point of the two connecting rods (1005) is located right below the valve rod (1307); the first valve (13) and the second valve (14) are respectively fixed on the supporting rods (1002) of the two detection devices (10).

8. The pier steel casing high-pressure flushing device as claimed in claim 1, wherein the first water inlet pipe (11) and the second water inlet pipe (12) are both hoses.

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