CN112575766A - Consolidate soft soil foundation tubular pile device - Google Patents
Consolidate soft soil foundation tubular pile device Download PDFInfo
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- CN112575766A CN112575766A CN202011375694.9A CN202011375694A CN112575766A CN 112575766 A CN112575766 A CN 112575766A CN 202011375694 A CN202011375694 A CN 202011375694A CN 112575766 A CN112575766 A CN 112575766A
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- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02D—FOUNDATIONS; EXCAVATIONS; EMBANKMENTS; UNDERGROUND OR UNDERWATER STRUCTURES
- E02D3/00—Improving or preserving soil or rock, e.g. preserving permafrost soil
- E02D3/12—Consolidating by placing solidifying or pore-filling substances in the soil
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- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02D—FOUNDATIONS; EXCAVATIONS; EMBANKMENTS; UNDERGROUND OR UNDERWATER STRUCTURES
- E02D15/00—Handling building or like materials for hydraulic engineering or foundations
- E02D15/02—Handling of bulk concrete specially for foundation or hydraulic engineering purposes
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- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02D—FOUNDATIONS; EXCAVATIONS; EMBANKMENTS; UNDERGROUND OR UNDERWATER STRUCTURES
- E02D2300/00—Materials
- E02D2300/0045—Composites
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- Agronomy & Crop Science (AREA)
- Environmental & Geological Engineering (AREA)
- Soil Sciences (AREA)
- Piles And Underground Anchors (AREA)
Abstract
The invention discloses a soft soil foundation pipe pile reinforcing device, which comprises a main pipeline and is characterized in that: the right end of the main pipeline is provided with a switching sleeve, the upper end and the lower end of the switching sleeve are respectively sleeved with a second auxiliary pipeline and a first auxiliary pipeline, an automatic switching mechanism is arranged in the main pipeline, a flow control mechanism is arranged in the adapter sleeve, the first auxiliary pipeline is internally provided with an adjusting and supplying mechanism which is fixed with the main pipeline, the flow control mechanism is fixed with the adapter sleeve, the adjusting and supplying mechanism is in transmission connection with the first auxiliary pipeline, the automatic switching mechanism comprises a main shaft, a first limit sleeve is fixed on the outer side of one end of the main shaft, the outer side of the first limiting sleeve is fixed with the inner wall of the main pipeline, the invention has the advantages of blocking debris flow, the soft soil is reinforced automatically according to the flow of the debris flow and the content of the stones, and the house is protected.
Description
Technical Field
The invention relates to the technical field of land reinforcement, in particular to a soft soil foundation pipe pile reinforcing device.
Background
In the construction process of the soft soil foundation, the reinforcement of the soft soil foundation is always the central importance in the whole construction process, and in order to improve the soft soil foundation to a suitable construction, the water needs to be pumped to the soft soil foundation so as to improve the performance of the soft soil foundation, and the pipe pile is usually inserted into the soft soil foundation to carry out the reinforcement. However, the pipe piles used for improving the soft soil foundation in the market are mostly directly inserted into the soft soil foundation through hammering, so that the pipe piles are labor-consuming and need to be improved, and the construction in the mountainous soft soil with frequent debris flow is difficult to solidify the soil to the effect of blocking the debris flow.
There are many methods for reinforcing soft soil foundations. The traditional method for reinforcing the soft soil foundation needs to solve the problems of a large amount of soil materials with small air permeability, difficult construction, high manufacturing cost, large interference of construction sites, large occupied area and poor applicability. The invention provides a powdery coal ash, which is mixed with lime and water to form a high-strength hard block, the hard block is different in texture due to different contents of the three substances, the harder the hard block is when the content of the powdery coal ash is higher, and the hard block is formed into a soft gel and is not easy to coagulate and disperse when the content of the water is higher. The invention provides a soft soil foundation pipe pile reinforcing device which can block debris flow, automatically reinforce soft soil according to the flow rate of the debris flow and the content of stones and protect a house.
Disclosure of Invention
The invention aims to provide a device for reinforcing a soft soil foundation pipe pile, which aims to solve the problems in the background technology.
In order to solve the technical problems, the invention provides the following technical scheme: the utility model provides a consolidate soft soil foundation tubular pile device, includes the trunk line, its characterized in that: the right end of the main pipeline is provided with a switching sleeve, the upper end and the lower end of the switching sleeve are respectively sleeved with a second auxiliary pipeline and a first auxiliary pipeline, an automatic switching mechanism is arranged inside the main pipeline, a flow control mechanism is arranged inside the switching sleeve, and an adjusting and supplying mechanism is arranged inside the first auxiliary pipeline; the automatic switching mechanism is used for automatically switching the pipeline to conduct drainage according to the flow rate of the debris flow, the flow control mechanism is used for doping the required materials when the flow rate of the debris flow is increased, and the adjusting and supplying mechanism is used for mixing and distinguishing different requirements according to the amount of the debris flow and the supplied materials.
According to the technical scheme, the automatic switching mechanism is fixed with the main pipeline, the flow control mechanism is fixed with the adapter sleeve, and the adjusting and supplying mechanism is in transmission connection with the first auxiliary pipeline.
According to the technical scheme, automatic switching mechanism includes the main shaft, main shaft one end outside is fixed with first spacing sleeve, the outside of first spacing sleeve is fixed mutually with the inner wall of trunk line, the main shaft has first electromagnetism piece with the fixed one end welding of first spacing sleeve, first spacing sleeve's bottom is provided with the second electromagnetism piece, the central authorities of second electromagnetism piece are provided with the head rod, the head rod run through the second electromagnetism piece and with second electromagnetism piece sliding connection, the one end of head rod is fixed with first electromagnetism piece, the other end welding of head rod has the baffle.
According to the technical scheme, the two sides of the first limiting sleeve are connected with the L-shaped connecting rod through the bearings, the other end of the L-shaped connecting rod is fixed with the first annular gasket, the outer side of the first limiting sleeve is provided with the built-in sleeve, a gap between the built-in sleeve and the first limiting sleeve is an upper channel, and the size of the first annular gasket is matched with that of the upper channel.
According to the technical scheme, the two sides of the end, far away from the first electromagnetic block, of the first limiting sleeve are correspondingly provided with the second connecting rods, one ends of the second connecting rods are fixedly provided with the telescopic rods, the other ends of the telescopic rods are fixedly provided with the second annular gaskets, the inner wall of the main pipeline is welded with the second limiting sleeves, gaps between the second limiting sleeves and the built-in sleeves are lower channels, and the size of the second annular gaskets is matched with that of the lower channels.
According to the technical scheme, the main shaft is provided with the internal thread and the external thread respectively, the internal thread is formed in the inner wall of the built-in sleeve and located on the outer side of the external thread of the main shaft, the supporting rods are correspondingly arranged on two sides of the inner portion of the inner thread groove of the built-in sleeve, the rotating shaft is connected to the inner portion of each supporting rod through the corresponding bearing, the grinding wheel is welded at the lower end of the rotating shaft, the spiral fan is welded at the other end of the rotating shaft, the air bag is sleeved on the outer portion of the spiral fan, the tension rope is fixed on the outer side of the rotating shaft, the nitrogen box is arranged on the outer side of.
According to the technical scheme, the flow control mechanism comprises a driving ball, wherein one half of the driving ball is made of sodium peroxide, the other half of the driving ball is made of magnesium, five auxiliary balls are correspondingly arranged on the outer side of the driving ball, the auxiliary ball at the top end of the driving ball is an electromagnetic ball, other four auxiliary balls are iron, five the outside of auxiliary ball all is provided with the trapezoidal baffle of magnesium, is located the below of the trapezoidal baffle of magnesium of drive ball below is fixed with first auxiliary conduit, is located the top of the trapezoidal baffle of magnesium of drive ball top is fixed with the second auxiliary conduit, is located the left side of the trapezoidal baffle of magnesium of drive ball left side is fixed with the supply pipeline, is located the right side of the trapezoidal baffle of magnesium on drive ball right side is fixed with the fuel pipeline, is located one side of the trapezoidal baffle of magnesium in drive ball the place ahead is fixed with the trunk line, is located one side of the trapezoidal baffle of magnesium at drive ball rear is provided with the moisturizing pipe.
According to the technical scheme, the other end of the supply pipeline is sleeved with a supply tank, powdery substances are arranged in the supply tank, the other end of the fuel pipeline is sleeved with a fuel tank, liquid is arranged in the fuel tank, and the other end of the water supply pipe is sleeved on a second auxiliary pipeline.
According to the above technical scheme, adjust supply mechanism and include the mixing shaft, the inside at first auxiliary pipeline is connected through the bearing at the both ends of mixing shaft, the outside welding of mixing shaft has driven gear, the top of mixing shaft is provided with the drive shaft, the inside at first auxiliary pipeline is connected through the bearing to the one end of drive shaft, the other end of drive shaft is fixed with fan-shaped fixture block, the teeth of a cogwheel have been seted up on the top of fan-shaped fixture block, the teeth of a cogwheel of fan-shaped fixture block is unanimous with driven gear tooth interval size, the below of fan-shaped fixture block is fixed with the third connecting rod, one side of third connecting rod is fixed with the stopper quarter butt.
According to the technical scheme, the adjusting and supplying mechanism further comprises a rotating disc, a plurality of channels are uniformly formed in the rotating disc, stretching filter screens are arranged in the channels, a baffle is fixed between every two channels, an arc limiting block is welded on one side, close to the fan-shaped clamping block, of the baffle, and the size of the limiting short rod is consistent with the width of the channels.
Compared with the prior art, the invention has the following beneficial effects: according to the invention, the automatic switching mechanism is arranged, and the pipeline is automatically switched to conduct drainage according to the flow rate of the debris flow; by arranging the flow control mechanism, when the flow of the debris flow is increased, the required materials are doped; through being provided with regulation supply mechanism, mix according to the mud-rock flow and supply material's quantity and distinguish the needs that realize different situations.
The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:
FIG. 1 is a schematic overall elevational cross-sectional structural view of the present invention;
FIG. 2 is a schematic view of the automatic switching mechanism of the present invention in partial cross-section;
FIG. 3 is a schematic perspective view of the spindle and the built-in sleeve of the present invention;
FIG. 4 is a schematic perspective view of the flow control mechanism of the present invention;
FIG. 5 is a schematic perspective view of the adjustment and replenishment mechanism of the present invention;
FIG. 6 is a schematic view of the flow control mechanism of the present invention in a first operating condition;
FIG. 7 is a schematic view of the flow control mechanism of the present invention in a second operating condition;
in the figure: 1. a main pipeline; 2. a first auxiliary duct; 3. a second auxiliary duct; 4. a drive ball; 5. an adapter sleeve; 101. a main shaft; 102. a first limit sleeve; 103. a sleeve is arranged inside; 1031. grinding a grinding wheel; 1032. an air bag; 1033. a rotating shaft; 104. a first annular gasket; 105. a second annular gasket; 106. a second limit sleeve; 107. a magnesium trapezoidal baffle; 108. a supply line; 109. a fuel conduit; 110. a water replenishing pipe; 201. a drive shaft; 202. a fan-shaped fixture block; 203. a third connecting rod; 204. rotating the disc; 205. a mixing shaft.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
Referring to fig. 1-7, the present invention provides the following technical solutions: the utility model provides a consolidate soft soil foundation tubular pile device, includes trunk line 1, its characterized in that: the right end of the main pipeline 1 is provided with a switching sleeve 5, the upper end and the lower end of the switching sleeve 5 are respectively sleeved with a second auxiliary pipeline 3 and a first auxiliary pipeline 2, an automatic switching mechanism is arranged inside the main pipeline 1, a flow control mechanism is arranged inside the switching sleeve 5, and an adjusting and supplying mechanism is arranged inside the first auxiliary pipeline 2; the automatic switching mechanism is used for automatically switching the pipeline to conduct drainage according to the flow rate of the debris flow, the flow control mechanism is used for doping the required materials when the flow rate of the debris flow is increased, and the adjusting and supplying mechanism is used for mixing and distinguishing different requirements according to the amount of the debris flow and the supplied materials.
The automatic switching mechanism is fixed with the main pipeline 1, the flow control mechanism is fixed with the adapter sleeve 5, and the adjusting and supplying mechanism is in transmission connection with the first auxiliary pipeline 2.
The automatic switching mechanism comprises a main shaft 101, a first limiting sleeve 102 is fixed to the outer side of one end of the main shaft 101, the outer side of the first limiting sleeve 102 is fixed to the inner wall of a main pipeline 1, a first electromagnetic block is welded to one end, fixed to the main shaft 101 and the first limiting sleeve 102, of the main shaft 102, a second electromagnetic block is arranged at the bottom end of the first limiting sleeve 102, a first connecting rod is arranged in the center of the second electromagnetic block, the first connecting rod penetrates through the second electromagnetic block and is in sliding connection with the second electromagnetic block, one end of the first connecting rod is fixed to the first electromagnetic block, a baffle is welded to the other end of the first connecting rod, and the trend of operation in a follow-up device is controlled by separation and lamination of the first electromagnetic block and.
The two sides of the first limiting sleeve 102 are connected with L-shaped connecting rods through bearings, the other end of each L-shaped connecting rod is fixed with a first annular gasket 104, the outer side of the first limiting sleeve 102 is provided with a built-in sleeve 103, a gap between the built-in sleeve 103 and the first limiting sleeve 102 is an upper channel, the size of the first annular gasket 104 is matched with the size of the upper channel, the size of the first annular gasket 104 is consistent with the size of the upper channel, and when the two are attached, the generation of leakage is avoided, and the subsequent operation of the device is influenced.
Two sides of one end, far away from the first electromagnetic block, of the first limiting sleeve 102 are correspondingly provided with second connecting rods, one ends of the second connecting rods are fixedly provided with telescopic rods, the other ends of the telescopic rods are fixedly provided with second annular gaskets 105, the inner wall of the main pipeline 1 is welded with second limiting sleeves 106, gaps between the second limiting sleeves 106 and the built-in sleeves 103 are lower channels, and the sizes of the second annular gaskets are matched with those of the lower channels; the mud water which flows out before the occurrence of the debris flow contains less stones and is mostly mud water, the mud water flows into the main pipe 1, the baffle plate is pushed to enable the first connecting rod which cannot be fixed to slide in the second electromagnetic block to push the main shaft 101 to move in the main pipe 1, the flow is small at the moment, the water flow impact is not enough to push the second annular gasket 105 to clamp a lower channel, the L-shaped connecting rod and the first annular gasket 104 at one end of the L-shaped connecting rod are small in channel impact, the upper channel opening is continuously opened, the water flow flows into the upper channel between the built-in sleeve 103 and the first limiting sleeve 102, the water storage stage before the occurrence of the debris flow is absorbed by the upper channel, and the operation of the subsequent steps is prevented from being influenced.
The spindle 101 is provided with an internal thread and an external thread respectively, the inner wall of the built-in sleeve 103 is positioned on the outer side of the external thread of the spindle 101 and is provided with an internal thread, two sides of the inner thread groove of the built-in sleeve 103 are correspondingly provided with support rods, the inner part of each support rod is connected with a rotating shaft 1033 through a bearing, the lower end of each rotating shaft 1033 is welded with a grinding wheel 1031, the other end of each rotating shaft 1033 is welded with a helical fan, the outer part of each helical fan is sleeved with an air bag 1032, the outer side of each rotating shaft 1033 is fixed with a tension rope, the outer side of the built-in sleeve 103; when the flow of the debris flow is increased, namely the impact of the mud-water mixed stone is increased, the debris flow into the main pipeline 1 causes large impact to the push plate, at the moment, the push plate pushes the main shaft 101 to move in the built-in pipeline 103 to be rotationally engaged with the built-in sleeve 103, external threads outside the main shaft 101 continuously rub with the grinding wheel 1031 while sliding in internal threads on the built-in pipeline 103, so that the grinding wheel 1031 on both sides reversely rotate to drive the rotating shafts 1033 on both sides to reversely rotate to stretch the tension ropes fixed on the rotating shafts, when the external threads on the main shaft 101 are disengaged from the internal threads on the built-in sleeve 103, the rotating shafts 1033 are driven to rapidly rotate under the action force of the retraction of the tension ropes to drive the air bags 1032 on the top of the rotating shafts to expand, the two air bags 1032 simultaneously expand to deform and expand to push the nitrogen tank switch, nitrogen in the nitrogen tank rushes into the built, be about to main shaft 101 along debris flow advances the reverse release of direction for first electromagnetic block and the laminating of second electromagnetic block circular telegram, simultaneously because debris flow strikes too big, make first annular gasket 104 laminating go up the passageway and block up, the impact of debris flow pushes away second annular gasket 105 simultaneously, make the telescopic link of second annular gasket 105 one side contract and loosen the jam to the lower passageway, make in debris flow flows into the device through the lower passageway, the device distinguishes automatically according to the size of debris flow and realizes opening the upper passageway or open the lower passageway.
The flow control mechanism comprises a driving ball 4, half of the driving ball 4 is made of sodium peroxide, the other half of the driving ball 4 is made of magnesium, five auxiliary balls are correspondingly arranged on the outer side of the driving ball 4, the auxiliary ball on the top end of the driving ball 4 is an electromagnetic ball, the other four auxiliary balls are made of iron, magnesium trapezoidal baffles 107 are arranged on the outer sides of the five auxiliary balls, a first auxiliary pipeline 2 is fixed below the magnesium trapezoidal baffle 107 below the driving ball 4, a second auxiliary pipeline 3 is fixed above the magnesium trapezoidal baffle 107 above the driving ball 4, a supply pipeline 108 is fixed on the left side of the magnesium trapezoidal baffle 107 on the left side of the driving ball 4, a fuel pipeline 109 is fixed on the right side of the magnesium trapezoidal baffle 107 on the right side of the driving ball 4, a main pipeline 1 is fixed on one side of the magnesium trapezoidal baffle 107 in front of the driving ball 4, a water supply pipe 110 is arranged on one side of the magnesium trapezoidal baffle 107 behind the driving ball 4, each auxiliary ball blocks one pipeline, and the auxiliary balls all operate independently, are opened independently when being opened and are discharged together, so that the discharge amount is unified.
The other end of the supply pipeline 108 is sleeved with a supply tank, powdery substances are arranged in the supply tank, the other end of the fuel pipeline 109 is sleeved with a fuel tank, liquid is arranged in the fuel tank, and the other end of the water supply pipe 110 is sleeved on the second auxiliary pipeline 3; when the debris flow is just opened, the flowing debris-free sludge mostly enters the device from the upper channel, the auxiliary ball above the driving ball 4 in the flow control mechanism is difficult to completely seal the second auxiliary pipeline 3 under the influence of gravity, at the moment, the driving ball 4 is rotated clockwise in the longitudinal direction, the water flowing into the device is pumped into the second auxiliary pipeline 3 by utilizing the wind pressure generated by the rotation of the driving ball 4, because half of the auxiliary ball 4 is made of sodium peroxide, the auxiliary ball 4 reacts with the water in the rotating process to generate sodium hydroxide and oxygen, because the water continuously flows into the second auxiliary pipeline 3, the generated oxygen leaks out along the gap between the auxiliary ball and the magnesium trapezoidal baffle 107, and when the driving ball 4 rotates at a high speed, the auxiliary ball below is driven to rotate in the reverse direction to generate negative pressure to pump the generated oxygen into the first auxiliary pipeline 2, when the flow of the debris flow is increased, namely, the impact of the mud-water mixed stone is increased, at the moment, the first electromagnetic block and the second electromagnetic block are attached to ensure that the electromagnetic ball above the driving ball 4 is electrified and adsorbed on the magnesium-made trapezoidal baffle plate 107 and simultaneously attracts the driving ball 4 below the driving ball 4 and the auxiliary ball below the driving ball 4 to move upwards, so that water and stone in the introducing device enter the first auxiliary pipeline, the driving ball 4 moves upwards and simultaneously limits the left, right and rear auxiliary balls, the powdery substance in the supply pipeline 108 is preferably pulverized coal ash, the combustion-supporting liquid in the combustion pipeline 109 leaks to be mixed with the water and the stone to fall down, at the moment, the driving ball 4 is rotated, because the other half material is magnesium, the combustion-supporting liquid is ignited by the spark generated by the friction with the magnesium-made trapezoidal baffle plate 107 which is also made of magnesium, the mountain stone blocks in the mud-water flow of the absorbing device are combusted, and the natural rock in the mud-stone flow, the oxygen pumped into the first auxiliary pipeline 2 in the previous step is used here to realize sufficient combustion of the stone block so as to avoid insufficient combustion caused by insufficient oxygen, the stone generates lime and carbon dioxide in the combustion process, at this time, because the auxiliary balls above the second auxiliary pipeline 2 do not block the first auxiliary pipeline 2 any more, the generated carbon dioxide rises to react with the driving balls 4 which become sodium hydroxide to generate water in the second auxiliary pipeline 3, and the generated water enters the water replenishing pipe 110.
Adjust supply mechanism and include mixing shaft 205, mixing shaft 205's both ends pass through the inside that the bearing is connected at first auxiliary pipeline 2, mixing shaft 205's outside welding has driven gear, mixing shaft 205's top is provided with drive shaft 201, the inside at first auxiliary pipeline 2 is passed through to the bearing and is connected to drive shaft 201's one end, drive shaft 201's the other end is fixed with fan-shaped fixture block 202, the teeth of a cogwheel have been seted up on fan-shaped fixture block 202's top, the teeth of a cogwheel of fan-shaped fixture block 202 and driven gear tooth interval size are unanimous, fan-shaped fixture block 202's below is fixed with third connecting rod 203, one side of third connecting rod 203 is fixed with the stopper quarter butt, the effect of this.
The adjusting and supplying mechanism further comprises a rotating disc 204, a plurality of channels are uniformly formed in the rotating disc 204, stretching filter screens are arranged in the channels, a baffle is fixed between every two channels, an arc-shaped limiting block is welded on one side of each baffle, which is close to the fan-shaped fixture block 202, and the size of the limiting short rod is consistent with the width of each channel; the driving shaft 201 is rotated clockwise, the driving shaft 201 drives the fan-shaped fixture blocks 202 on two sides of the driving shaft, the third connecting rod and the limit short rod to rotate, the limit short rod and a channel formed in the rotating disc 204 are equal in size, the rotating disc 204 is driven to rotate clockwise, the stone blocks falling into the first auxiliary pipeline 2 fall into the channel on the rotating disc 204 and are covered by the tensile filter screen, part of mixed coal ash is adhered to the tensile filter screen while water and powdered coal ash seep out of the filter screen, the rest water and the rest coal ash enter the mixing shaft 205, the gear teeth at the top end of the fan-shaped fixture block 202 are meshed with the driven gear on the outer side of the mixing shaft 205 to drive the driven gear to rotate anticlockwise and the mixing shaft 205 to, in the process that the driving shaft 201 continuously rotates, the limiting short rod continuously fits with the channel to push out the residual stones in the channel to fall into the lower part of the device for later use; when the strength of the debris flow is continuously increased, stones entering the device are also continuously increased, lime generated by combustion is increased and attached to the inner wall of the device, the high-temperature pile device is prevented from being damaged, meanwhile, muddy water outside the device is isolated from absorbing heat generated by combustion, and the combustion efficiency is reduced, when the stones are increased, more stones fall into a channel on a rotating disc 204, the gravity of the stones is increased, the rotating disc 204 is forced to rotate anticlockwise, the stones falling into the channel fall automatically under the influence of the gravity, the fly ash remained on a stretching filter screen originally adhered and then in the channel is taken away by friction for two times, the content of the fly ash is increased, the hardness of a product formed by mixing the lime, the fly ash and water is increased, and the stone is discharged out of the device by a second auxiliary pipeline 2 and enters the underground of a house to replace hard blocks under an; when stones are increased, carbon dioxide generated by combustion is also increased continuously, the carbon dioxide reacts with the driving ball 4 which is made of sodium hydroxide continuously to generate a large amount of water, at the moment, the content of the water of the lime, the fly ash and the water is increased, so that the generated polymer is changed into soft gel, the soft soil in the original soft soil foundation is structurally damaged after being impacted to generate lateral sliding, and the generated soft gel polymer is driven to replace the position of the original peripheral soft soil to wrap the hard block generated in the previous step to protect the house foundation from erosion.
It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.
Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.
Claims (10)
1. The utility model provides a consolidate soft soil foundation tubular pile device, includes trunk line (1), its characterized in that: the right-hand member of trunk line (1) is provided with adapter sleeve (5), second auxiliary pipeline (3) and first auxiliary pipeline (2) have been cup jointed respectively to the last lower extreme of adapter sleeve (5), the inside of trunk line (1) is provided with automatic switching mechanism, the inside of adapter sleeve (5) is provided with flow control mechanism, the inside of first auxiliary pipeline (2) is provided with adjusts supply mechanism.
2. The device for reinforcing the tubular pile of the soft soil foundation according to claim 1, wherein: the automatic switching mechanism is fixed with the main pipeline (1), the flow control mechanism is fixed with the adapter sleeve (5), and the adjusting and supplying mechanism is in transmission connection with the first auxiliary pipeline (2).
3. The device for reinforcing the tubular pile of the soft soil foundation according to claim 2, wherein: automatic switching mechanism includes main shaft (101), main shaft (101) one end outside is fixed with first limit sleeve (102), the outside of first limit sleeve (102) is fixed mutually with the inner wall of trunk line (1), main shaft (101) have first electromagnetism piece with the fixed one end welding of first limit sleeve (102), the bottom of first limit sleeve (102) is provided with the second electromagnetism piece, the central authorities of second electromagnetism piece are provided with the head rod, the head rod run through the second electromagnetism piece and with second electromagnetism piece sliding connection, the one end of head rod is fixed with the first electromagnetism piece, the other end welding of head rod has the baffle.
4. The device for reinforcing the tubular pile of the soft soil foundation according to claim 3, wherein: the two sides of the first limiting sleeve (102) are connected with L-shaped connecting rods through bearings, a first annular gasket (104) is fixed to the other end of each L-shaped connecting rod, a built-in sleeve (103) is arranged on the outer side of the first limiting sleeve (102), a gap between the built-in sleeve (103) and the first limiting sleeve (102) is an upper channel, and the size of the first annular gasket (104) is matched with that of the upper channel.
5. The device for reinforcing the tubular pile of the soft soil foundation according to claim 4, wherein: the utility model discloses a pipeline, including trunk line (1), first spacing sleeve (102), first electromagnetism piece, second spacing sleeve (106), first spacing sleeve (102) are kept away from the one end both sides correspondence of first electromagnetism piece and are provided with the second connecting rod, the one end of second connecting rod is fixed with the telescopic link, the other end of telescopic link is fixed with second annular packing ring (105), the welding has second spacing sleeve (106) on the inner wall of trunk line (1), the clearance between second spacing sleeve (106) and built-in sleeve (103) is the lower passageway, the size of second annular packing ring (105) is identical with the size of lower passageway.
6. The device for reinforcing the tubular pile of the soft soil foundation according to claim 5, wherein: the novel multifunctional spindle is characterized in that an internal thread and an external thread are respectively arranged on the spindle (101), the outer side of the external thread of the spindle (101) is located on the inner wall of the built-in sleeve (103), the internal thread is formed, supporting rods are correspondingly arranged on two sides of the inner thread groove of the built-in sleeve (103), a rotating shaft (1033) is connected to the inside of each supporting rod through a bearing, a grinding wheel (1031) is welded to the lower end of the rotating shaft (1033), a spiral fan is welded to the other end of the rotating shaft (1033), an air bag (1032) is sleeved on the outside of the spiral fan, a tension rope is fixed to the outer side of the rotating shaft (1033), a nitrogen box is arranged on the outer side of the built-in sleeve (103), and a switch of.
7. The device for reinforcing the tubular pile of the soft soil foundation according to claim 6, wherein: the flow control mechanism comprises a driving ball (4), wherein half of the material of the driving ball (4) is sodium peroxide, the other half of the material of the driving ball is magnesium, the outer side of the driving ball (4) is correspondingly provided with five auxiliary balls, the auxiliary ball at the top end of the driving ball (4) is an electromagnetic ball, other four auxiliary balls are iron, the outer sides of the five auxiliary balls are respectively provided with a magnesium trapezoidal baffle (107), a first auxiliary pipeline (2) is fixed below the magnesium trapezoidal baffle (107) below the driving ball (4), a second auxiliary pipeline (3) is fixed above the magnesium trapezoidal baffle (107) above the driving ball (4), a supply pipeline (108) is fixed on the left side of the magnesium trapezoidal baffle (107) on the left side of the driving ball (4), and a fuel pipeline (109) is fixed on the right side of the magnesium trapezoidal baffle (107) on the right side of the driving ball (4), be located one side of the trapezoidal baffle of magnesium (107) in drive ball (4) the place ahead is fixed with trunk line (1), is located one side of the trapezoidal baffle of magnesium (107) at drive ball (4) rear is provided with moisturizing pipe (110).
8. The device of claim 7, wherein the pile is characterized in that: the other end of the supply pipeline (108) is sleeved with a supply tank, powder substances are arranged in the supply tank, the other end of the fuel pipeline (109) is sleeved with a fuel tank, liquid is arranged in the fuel tank, and the other end of the water supply pipe (110) is sleeved on the second auxiliary pipeline (3).
9. The device for reinforcing the tubular pile of the soft soil foundation according to claim 8, wherein: adjust supply mechanism and include mixing shaft (205), the inside at first auxiliary pipeline (2) is passed through the bearing connection at the both ends of mixing shaft (205), the outside welding of mixing shaft (205) has driven gear, the top of mixing shaft (205) is provided with drive shaft (201), the inside at first auxiliary pipeline (2) is passed through the bearing connection to the one end of drive shaft (201), the other end of drive shaft (201) is fixed with fan-shaped fixture block (202), the teeth of a cogwheel have been seted up on the top of fan-shaped fixture block (202), the teeth of a cogwheel of fan-shaped fixture block (202) and driven gear tooth interval size are unanimous, the below of fan-shaped fixture block (202) is fixed with third connecting rod (203), one side of third connecting rod (203) is fixed with the spacing quarter butt.
10. The device for reinforcing the tubular pile of the soft soil foundation according to claim 9, wherein: the adjusting and supplying mechanism further comprises a rotating disk (204), a plurality of channels are uniformly formed in the rotating disk (204), tensile filter screens are arranged in the channels, a plurality of baffles are fixed between every two channels, arc-shaped limiting blocks are welded on one sides, close to the fan-shaped clamping blocks (202), of the baffles, and the size of each limiting short rod is consistent with the width of each channel.
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CN202011375694.9A CN112575766A (en) | 2020-11-30 | 2020-11-30 | Consolidate soft soil foundation tubular pile device |
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Application publication date: 20210330 |