The present disclosure is directed to a foundation system for various ground structures, and particularly, to a foundation system for collapsible soils.
The “background” description provided herein is for the purpose of generally presenting the context of the disclosure. Work of the presently named inventors, to the extent it is described in this background section, as well as aspects of the description which may not otherwise qualify as prior art at the time of filing, are neither expressly or impliedly admitted as prior art against the present invention.
Generally, foundations connect above ground portion of a structure with ground such that a load of the above ground portion is evenly distributed to the ground. A foundation can be a shallow foundation or a deep foundation depending on strength of soil, type of buildings, and size of buildings. Foundation engineers have encountered problems developing a new foundation system for collapsible soils. Collapsible soils possess considerable in-situ dry strength that is largely lost when the soils become wetted. Further, the amount and type of treatment required for such soils depends on the depth of the collapsible soils and support required for the proposed structure. In many cases, deep foundations are considered to transmit foundation loads to suitable bearing strata below the collapsible soil deposit. However, developing a foundation design for such collapsible soils is a tedious task. Therefore, there is a need remains to develop a foundation system that is cost effective and capable of absorbing tensile and lateral loads.
In an exemplary embodiment, a foundation system for collapsible soils is described. The foundation system includes a below-ground rigid raft foundation to bear a load for an above-ground structure. A plurality of granular cushions formed below the below-ground rigid raft foundation and the granular cushions are configured for uniform load distribution of the below-ground rigid raft foundation. A plurality of piles is formed below the raft foundation and is configured to bear a load of the above-ground structure and the below-ground rigid raft foundation. A plurality of below-ground stone columns is configured to stabilize the below-ground rigid raft foundation and the below-ground stone columns are encapsulated with a non-woven geofabric. The below-ground raft foundation is adjacent and above the below-ground stone columns, the granular cushions are present between neighboring below-ground stone columns, and the granular cushions are present between the below-ground stone columns and the piles. The below-ground stone columns have a cementing agent for stabilization.
In some embodiments, the piles are steel and cylindrical in shape and the piles are filled with a concrete.
In some embodiments, the piles are coated with an epoxy.
In some embodiments, the piles have a length of from 15 m to 60 m.
In some embodiments, the stone columns have a diameter of from 0.5 m to 0.75 m and are spaced apart from one another by approximately 1.5 m to 3 m from center to center of adjacent below-ground stone columns.
In some embodiments, the stone columns have a depth of from 6 m to 10 m below the above-ground structure.
In some embodiments, the stone columns have a depth of at most 31 m below the above ground structure.
In some embodiments, the non-woven geofabric is selected from a group consisting of polypropylene and polyethylene.
In some embodiments, the non-woven geofabric has an amount of polypropylene of from wt. % to 70 wt. % of the geofabric and an amount of polyethylene of from 30 wt. % to 40 wt. % of the geofabric.
In some embodiments, the non-woven geofabric has a thickness of from 1 mm to 10 mm.
In some embodiments, the non-woven geofabric has a specific gravity of from 0.8 to 1.
In some embodiments, the cementing agent is ordinary cement Portland (OPC) with an amount of OPC of from 10 wt. % to 15 wt. % of the stone column.
In some embodiments, the cementing agent has a density of from 125 kg/m 3 to 350 kg/m3.
In some embodiments, the cementing agent has an amount of lime of from 60 wt. % to 67 wt. % of the cementing agent, an amount of silica of from 17 wt. % to 25 wt. % of the cementing agent, an amount of alumina of from 3 wt. % to 8 wt. % of the cementing agent, an amount of iron oxide of from 0.5 wt. % to 0.6 wt. % of the cementing agent, a total amount of K2O and Na2O of from 0.2 wt. % to 1.5 wt. % of the cementing agent, and an amount of magnesia of from 0.1 wt. % to 1 wt. % of the cementing agent.
In some embodiments, the cementing agent has a specific gravity of from 3 to 4.
In some embodiments, the cementing agent has a Blaine's specific surface of from 2400 cm2/kg to 2500 cm2/kg.
In some embodiments, the plurality of below-ground stone columns has reinforcing bars, wherein the reinforcing bars have a length of 1.1-2 times an average width of the stone column. In some embodiments, the reinforcing bars are angled to form conical structures comprising an upper conical structure and a lower conical structure, wherein the upper conical structure penetrates the lower conical structure by no more than 0.5 times the height of the lower conical structure.
The foregoing general description of the illustrative present disclosure and the following detailed description thereof are merely exemplary aspects of the teachings of this disclosure and are not restrictive.
A more complete appreciation of this disclosure and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
In the drawings, like reference numerals designate identical or corresponding parts throughout the several views. Further, as used herein, the words “a,” “an” and the like generally carry a meaning of “one or more,” unless stated otherwise.
Furthermore, the terms “approximately,” “approximate,” “about,” and similar terms generally refer to ranges that include the identified value within a margin of 20%, 10%, or preferably 5%, and any values there between.
Referring to
The foundation system 100 further includes a plurality of granular cushions 110 formed below the raft foundation 102. More particularly, the plurality of granular cushions 110 may be disposed immediately below the lower surface 108 of the raft foundation 102. The plurality of granular cushions 110 is configured for uniform load distribution of the raft foundation 102. In certain embodiments, the granular cushions 110 are geotextile bags filled with sand, gravel, pebbles, slag, topsoil, ballast, gypsum, fill, granite dust, or other aggregated materials. In certain embodiments, the aggregated materials have a size ranging from 10 mm to 150 mm, preferably 20 mm to 140 mm, preferably 30 mm to 130 mm, preferably 40 mm to 120 mm, preferably 50 mm to 110 mm, preferably 60 mm to 100 mm, preferably 70 mm to 90 mm, or 80 mm. In certain embodiments, the granular cushions have a length of 1 m to 20 m, preferably 2 m to 19 m, preferably 3 m to 18 m, preferably 4 m to 17 m, preferably 5 m to 16 m, preferably 6 m to 15 m, preferably 7 m to 14 m, preferably 8 m to 13 m, preferably 9 m to 12 m, or preferably 10 m.
The foundation system 100 further includes a plurality of piles 112 formed below the raft foundation 102. Particularly, the plurality of piles 112 is formed immediately below the lower surface 108 of the raft foundation 102. Each of the plurality of piles 112 includes a top end 112A configured to connect with the lower surface 108 of the raft foundation 102 and a bottom end 112B. The plurality of piles 112 is configured to bear a load of the above ground structure 104 and the raft foundation 102. As shown in
In some embodiments, the piles 112 are coated with an epoxy. As the steel piles are subjected to corrosion (pH<7), the epoxy coating on the piles helps to prevent or minimize corrosion thereof, and thereby improve useful life of the piles 112. In certain embodiments, the epoxy may be bisphenol, aliphatic, halogenated, diluents, or glycidylamine epoxies. In certain embodiments, additional thickness is provided to the piles 112 to improve useful life thereof, such as 1 m, 2 m, 3 m, 4 m, or 5 m. In some embodiments, the piles 112 have a length defined between the top end 112A and the bottom end 112B. The length of the pile 112 may be from 15 m to 60 m, preferably 20 m to 55 m, preferably 25 m to 50 m, preferably 30 m to 45 m, preferably 35 m to 40 m, or 37.5 m. Also, the pile 112 can carry a load in a range of 300 N to 1200 N, preferably 375 N to 1125 N, preferably 450 N to 1050 N, preferably 525 N to 975 N, preferably 600 N to 900 N, preferably 675 N to 825 N, or 750 N. In certain embodiments, the length of the piles 112 may be longer than 60 m depending on the application and, accordingly, load carrying capacity can be increased further, such as 65 m, 70 m, 75 m, 80 m, 85 m, 90 m, 95 m, or 100 m.
The foundation system 100 further includes a plurality of stone columns 114 configured to stabilize the raft foundation 102. Each of the plurality of stone columns 114 has a top end 114A connected to the lower surface 108 of the raft foundation 102 and a bottom end 114B, as such the raft foundation 102 is formed adjacent and above the stone columns 114. In certain embodiments, there are at least 3 granular cushions 110 for every 1 pile 112, preferably 3 cushions 110 for every 1 pile 112, preferably 4 cushions, preferably 5 cushions, preferably 6 cushions, preferably 7 cushions, preferably 8 cushions, preferably 9 cushions, or 10 stone cushions 110 for every pile 112. In certain embodiments, there are at least 2 stone columns 114 for every 1 pile 112, preferably 3 columns 114 for every 1 pile 112, preferably 4 columns, preferably 5 columns, preferably 6 columns, preferably 7 columns, preferably 8 columns, preferably 9 columns, or 10 stone columns 114 for every pile 112. In certain embodiments, there are at least 2 granular cushions 110 for every 1 stone column 114, preferably 4 cushions, preferably 6 cushions, preferably 8 cushions, or 10 stone cushions 110 for every stone column 114. In certain embodiments, the stone columns were coupled with supports such as steel, brick, and wood. In certain embodiments, the stone columns 114 were reinforced with concrete, carbon steel, wire mesh, fiber-reinforced plastic, wire, cross-ties, or basalt fiber. In certain embodiments, the stone columns were reinforced with a polymer filler (polyurethane), binder, or adhesive. In certain embodiments, the stone columns are reinforced with a curable polyurethane injection, a curable concrete, or other curable materials. In some embodiments, the stone columns are reinforced with a matrix of concrete, ordinary Portland cement, polyurethane, organic polymers, or inorganic matrices. In further embodiments, the reinforced matrix may include concrete, carbon steel, wire mesh, fiber-reinforced plastic, wire, cross-ties, or basalt fiber. Further, the granular cushions 110 are present between neighboring stone columns 114. Particularly, the granular cushion 110 is formed between two adjacent stone columns 114 immediately below the lower surface 108 of the raft foundation 102. Also, the granular cushions 110 are present between the stone columns 114 and the piles 112. As shown in
In certain embodiments, the rigid raft foundation 102 extends above the cylindrical hole fitted for the stone column as to allow the stone column 114 to be partially encapsulated by the rigid raft foundation. In certain embodiments, the rigid raft foundation 102 has a thickness of 0.5 m to 10 m, preferably 1 m to 9 m, preferably 2 m to 8 m, preferably 3 m to 7 m, preferably 4 m to 6 m, or 5 m. In certain embodiments, the stone columns 114 protrude into the thickness of the rigid raft foundation 102 in a range from 10 cm to 1 m, preferably 100 cm to 900 cm, preferably 200 cm to 800 cm, preferably 300 cm to 700 cm, preferably 400 cm to 600 cm, or 500 cm. In certain embodiments, the steel piles 112 protrude into the thickness of the rigid raft foundation 102 in a range from 10 cm to 1 m, preferably 100 cm to 900 cm, preferably 200 cm to 800 cm, preferably 300 cm to 700 cm, preferably 400 cm to 600 cm, or 500 cm.
In certain embodiments, the granular cushions 110 form around the cylindrical holes fitted for the stone columns 114, spanning across the entire circumference of the cylindrical hole. In certain embodiments, the granular cushions are in direct contact with the rigid raft foundation 102 and the stone columns 114 in which the granular cushions 110 surround the entire circumference of the cylindrical hole fitted for the stone columns 114 which protrude into the thickness of the rigid raft foundation 102.
The gravel in the cylindrical hole is gradually compacted as the vibrator is withdrawn. The gravel used for preparing the stone column 114 has size in a range of 10 to 400 mm, preferably 25 to 375 mm, preferably 50 to 350 mm, preferably 75 to 325 mm, preferably 100 to 300 mm, preferably 125 to 275 mm, preferably 150 to 250 mm, preferably 175 to 225 mm, or 200 mm. In certain embodiments, the stone columns 114 may have a slenderness ratio, length to diameter ratio, of 5, 10, 15, 20, 25, 40, 50, or 60. In certain embodiments,
In some embodiments, each of the plurality of stone columns 114 has a diameter from 0.5 m to 0.75 m, preferably 0.525 m to 0.725 m, preferably 0.55 m to 0.7 m, preferably 0.575 m to m, preferably 0.6 m to 0.65 m, or 0.625 m and the plurality of stone columns 114 are spaced apart from one another by approximately 1.5 m to 3 m from center to center of an adjacent stone column 114, preferably 1.6 m to 2.9 m, preferably 1.7 m to 2.8 m, preferably 1.8 m to 2.7 m, preferably 1.9 m to 2.6 m, preferably 2 m to 2.5 m, preferably 2.1 m to 2.4 m, preferably 2.2 m to 2.3 m, or 2.25 m. In other words, a center to center distance between two adjacent stone columns 114 is in the range of 1.5 m to 3 m. In some embodiments, the spacing between the stone columns 114 and the piles 112 is 1 to 2 m, preferably 1.1 to 1.9 m, preferably 1.2 to 1.8 m, preferably 1.3 to 1.7 m, preferably 1.4 to 1.6 m, or 1.5 m. In some embodiments, each of the plurality of stone columns 114 has a depth from 6 m to 10 m below the above ground structure 104, preferably 6.5 m to 9.5 m, preferably 7 m to 9 m, preferably 7.5 m to 8.5 m, or 8 m. Particularly, a length of the stone column 114 defined between the top end 114A and the bottom end 114B is in a range of 6 m to 10 m, preferably 6.5 m to 9.5 m, preferably 7 m to 9 m, preferably 7.5 m to 8.5 m, or 8 m. In some embodiments, each of the plurality of stone columns 114 has a depth of at most 31 m below the above ground structure 104 depending on the application of the foundation system 100, and may be increased further such as 32 m, 33 m, 34 m, 35 m, 36 m, 37 m, 38 m, 39 m, or 40 m.
In certain embodiments, the stone in the stone columns is marble, limestone, sandstone, granite, gneiss, basalt, trap, slate, quartzite, laterite, murum, or a mixture of any two or more components. In certain embodiments, the stone has a size that ranges from 10 to 500 mm, preferably 35 to 575 mm, preferably 60 to 550 mm, preferably 85 to 525 mm, preferably 110 to 500 mm, preferably 135 to 420 mm, preferably 160 to 450 mm, preferably 185 to 425 mm, preferably 210 to 400 mm, preferably 235 to 375 mm, preferably 260 to 325 mm, preferably 285 to 300 mm, or 290 mm. In certain embodiments, the stone has a density that ranges from 100 kg/m3 to 500 kg/m3, preferably 125 kg/m3 to 475 kg/m3, preferably 150 kg/m3 to 450 kg/m3, preferably 175 kg/m3 to 425 kg/m3, preferably 200 kg/m3 to 400 kg/m3, preferably 225 kg/m3 to 375 kg/m3, preferably 250 kg/m3 to 350 kg/m3, preferably 275 kg/m3 to 325 kg/m3, or 300 kg/m3.
In a preferable embodiment of the invention one or more of the stone columns, and preferably all of the stone columns 114, contain a series of tiered angled reinforcing bars. Each reinforcing bar has a length of 1.1-2 times the average width of the stone column, preferably 1.2-1.9 times the average width of the stone column, preferably 1.3-1.8 times the average width of the stone column preferably 1.4-1.7 times the average width of the stone column, preferably 1.5-1.6 times the average width of the stone column, or 1.55 times the average width of the stone column. The angled reinforcing bars are arranged circumferentially in the stone column such that a top end of each angled reinforcing bar is at an outer most portion of the stone column. The angled reinforcing bar is angled such that a bottom end of the reinforcing bar is close to the long central axis of the stone column. Preferably the bottom end of the reinforcing bar is located within a distance of 0.1 times the average width of the stone column from the central axis of the stone column. The number of angled reinforcing bars per tier (stage) may vary. Preferably the density of the angled reinforcing bars is set such that there is one reinforcing bar for each 0.1-0.5 times a distance of the circumference of the stone column preferably each 0.2-0.3 times a distance of the circumference of the stone column, or 0.25 times a distance of the circumference of the stone column. Arranged in this way each tier of angled reinforcing bars may be viewed as an inverted conical structure. The conical structures are nested such that an upper conical structure penetrates a lower conical structure by no more than 0.5 times the height of the lower conical structure, preferably, 0.2-0.4 times the height of the lower conical structure, or 0.3 times the height of the lower conical structure. The tiered conical structures may begin at the bottom of the stone column repeating to the top of the stone column. Reinforcing bars may be placed during the assembly of the stone column and activation of the cementing agent. The inclusion of tiers of reinforcing bars aids in halting lateral displacement of the foundation system during seismic events.
In some embodiments, the plurality of stone columns 114 is encapsulated with a non-woven geofabric. In an example, the non-woven geofabric material used in the present disclosure is Terram 3000 (T3000). Typically, referring to
In some embodiments, the non-woven geofabric is selected from a group consisting of polypropylene and polyethylene. In some embodiments, the non-woven geofabric has an amount of polypropylene from 60 wt. % to 70 wt. % of the geofabric, preferably 61 wt. % to 69 wt. %, preferably 62 wt. % to 68 wt. %, preferably 63 wt. % to 67 wt. %, preferably 64 wt. % to 66 wt. %, or 65 wt. % and an amount of polyethylene from 30 wt. % to 40 wt. % of the geofabric, preferably 31 wt. % to 39 wt. %, preferably 32 wt. % to 38 wt. %, preferably 33 wt. % to 37 wt. %, preferably 34 wt. % to 36 wt. %, or 35 wt. %. In an example, the Terram geofabric is made from 67% polypropylene and 33% polyethylene. In some embodiments, the non-woven geofabric has a thickness from 1 mm to 10 mm, preferably 2 mm to 9 mm, preferably 3 mm to 8 mm, preferably 4 mm to 7 mm, preferably 5 mm to 6 mm, or 6.5 mm and a specific gravity from 0.8 to 1, preferably 0.82 to 0.98, preferably 0.84 to 0.96, preferably 0.86 to 0.94, preferably 0.88 to 0.92, or 0.9. In an example, the Terram geofabric has 1.0 mm thickness and the specific gravity is 0.9. The structural characteristics of Terram geofabric are: a maximum load (per 200 mm) is 2800 N, preferably 2810 N, preferably 2820 N, preferably 2830 N, preferably 2840 N, or 2850 N and extension at maximum load is 60%, preferably 61%, preferably 62%, preferably 63%, preferably 64%, or 65%. Further, Terram is resistant to all naturally occurring soil alkalis—even 10% sodium hydroxide has little effect. Terram geofabric has resistance to all naturally occurring soil acids—(i.e., to acids of pH>2), and to general chemical attack, for example, water, oil, and petrol.
In some embodiments, each of the plurality of stone columns 114 has a cementing agent. The cementing agent is employed to stabilize the stone columns 114. In certain embodiments, the cementing agent may be a calcite, aragonite, dolomite, siderite, silicate, sulfate, or chloride. Referring to
In some embodiments, the cementing agent has a specific gravity from 3 to 4 preferably 3.1 to 3.9, preferably 3.2 to 3.8, preferably 3.3 to 3,7, preferably 3.4 to 3.6, or 3.5; and a Blaine's specific surface from 2400 cm2/kg to 2500 cm2/kg, preferably 2410 cm2/kg to 2490 cm2/kg, preferably 2420 cm2/kg to 2480 cm2/kg, preferably 2430 cm2/kg to 2470 cm2/kg, preferably 2440 cm2/kg to 2460 cm2/kg, or 2450 cm2/kg. Particularly, specific gravity and the Blaine's specific surface of the OPC are 3.15, 24 and 2415 cm2/kg, respectively. Also, physical properties such as initial setting time and final setting time of the OPC are 1 hour and 10 hours, respectively. In some embodiments, the initial setting time and final setting time are 2 hours and 11 hours, or 3 hours and 12 hours, or 4 hours and 13 hours, or 5 hours and 14 hours.
According to the present disclosure, an analytical model is developed for predicting the load carrying capacity (Qg(u)) of the foundation system 100. The analytical model is developed based on various factors such as dimensional characteristics of the piles 112 and the stone columns 114, total number of the piles 112 and the stone columns 114 in the foundation system 100, number of the piles 112 and the stone columns 114 in each row and columns of the foundation system 100, physical properties of the collapsible soils, and bearing capacity factor deduced from a Meyerhof chart, as shown in
The analytical model is
Wherein:
According to the present disclosure, the foundation system 100 is preferred for collapsible soils. The foundation system 100 includes the rigid raft foundation 102, the cylindrical steel piles 112, and the encapsulated and stabilized stone columns 114 combined in one foundation support for supporting the collapsible soils. Enough stone columns 114 are provided in the foundation system 100 to accelerate the rate of consolidation of the soil foundation. Soil consolidation refers to the mechanical process by which soil changes volume gradually in response to a change in pressure. The foundation system 100 of the present disclosure has improved carrying capacity and helps to modify soil foundation to a new upgraded composite ground. Further, the foundation system 100 of the present disclosure helps to reduce cost of geotechnical works. The analytical model of the present disclosure helps to predict carrying capacity of the foundation system 100.
Obviously, numerous modifications and variations of the present disclosure are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the invention may be practiced otherwise than as specifically described herein.
Number | Name | Date | Kind |
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6672015 | Cognon | Jan 2004 | B2 |
Number | Date | Country |
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207934028 | Oct 2018 | CN |
111648348 | Sep 2020 | CN |
Entry |
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