RU28498U1 - SCREW PILES - Google Patents

Description

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The utility model relates to the construction, in particular, to the construction of screw piles designed to work in difficult hydrological conditions, mainly at a considerable depth in soft soils.

Scientific research and production experience with the use of screw piles have confirmed their technical and economic feasibility. The initial costs of manufacturing such piles are largely paid off due to the possibility of their subsequent unscrewing. These advantages make screw piles a leading place in those sectors of construction where the time spent on immersion, versatility of application, bearing capacity, reliability in work and the possibility of their repeated use are of paramount importance. A screw pile, as a rule, is a cylindrical tubular barrel with a tapered tip and a welded screw blade. Immersion of screw piles is carried out using special devices - screwing mechanisms (capstans), which provide for the rotation of the tool - screw piles. A very promising direction is to consider the possibility of using methods of immersion of screw piles without rotation of the immersed element, for example, by a vibro-method. The vibration method has found wide application in construction. At present, numerous studies have been carried out on the application of the vibro-method for various purposes, namely: for dipping sheet piles, piles, drilling shallow wells without rotating the tool, arranging sand piles and compacting sand soils.

Q02125257

SCREW PILES

This experience is most fully generalized in the literature 1. A theory of oscillations of the immersed element (tongue, pile, pipes and shells) has also been developed. As for the immersion and extraction of screw piles with a large broadened heel with a diameter of 850 - 1000 mm, designed to work in weak alluvial silty sands with interlayers of gravel and clay, a number of problems arise here, one of which is the creation of the construction of large diameter screw piles capable of work effectively not only with screwdriving, but also with vibration immersion.

Known screw pile 2, including; th hollow metal barrel with a tip and blades, the lower of which have a length less than the length of the upper. The barrel is equipped with a diaphragm located between the lower end of the barrel and the tip. The tip is made triangular, and the blades are flat sheet with a cut; its edge. The upper and lower blades are located at an angle of (7 - 20) ° to the plane of the diaphragm with the cutting orientation; its edges in the direction of ingrowth; The tip and the blades of the pile are equipped with stiffening ribs located along the lateral faces of the tip and along the sides of the blades, decubitus, cutting them; to their edges. When a pile having the design described above is immersed in the soil, additional soil resistance occurs, which leads to the need for an increase in torque. This is a disadvantage of the known screw piles 2, since its screwing can only be ensured with an additional load.

A screw anchor 3 is known, including a pointed barrel with a screw blade, the inlet of which is made with a cutting edge located in plan at an angle to the curve bounding the blade. The cutting edge of the lead-in is made in the plan along a parabola, and the angle formed by the parabola and the curve bounding the blade at

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their conjugation does not exceed the angle of friction of the blade material on the ground. A disadvantage of the known screw anchor 3, as well as screw piles 2, is that it can be screwed into the ground only if there is an additional load. This is due to the fact that the helical blade of the anchor is located within the cylindrical barrel of the anchor, without going to its lower conical part.

Anchor foundation 4 is also known, including a hollow shaft consisting of an upper section, a transitional section in the form of a prismatoid and a lower section. The lower section of the barrel is equipped with a helical blade. The diameter of the lower section is less than the diameter of the upper section. Windows are made in the walls of the transitional section of the barrel, through which soil cut through by a screw blade is fed into the prismaticoid, which helps to reduce torque when tightening. However, the known anchor foundation 4 has an unreasonably complex design. In addition, the lower cylindrical section of the barrel has a large length with a small diameter. A significant difference in the diameters of the upper and lower parts of the anchor foundation leads to an increase in soil adhesion along the lateral surface of the anchor. The consequence of this is an increase in the required amount of torque, which is a significant drawback of the known anchor foundation 4.

The closest in technical essence to the proposed utility model is a screw pile, selected as a prototype, the design of which is described in method 5, intended for immersion of a screw pile in the ground. The pile has a cylindrical tubular trunk and a conical tip equipped with a helical blade made of individual elements. A threaded rod is located on the upper surface of the conical tip for connecting the conical tip to the cylindrical section of the pile.

representing a tubular shell filled with concrete.

The disadvantage of a screw pile, known from literature 5, is a technologically difficult solution to a screw blade, consisting of separate elements, as well as its low carrying capacity. Another disadvantage of a screw pile is that this pile can only be used once. After filling the pile shaft with concrete, the pile can no longer be removed from the ground.

The objective of the proposed utility model is the development of the design of a screw pile with an increased load; it is capable of influencing vertical and horizontal loads while improving the reliability and productivity of the process of immersion and extraction, drained; carried out by a vibro-shock method.

To achieve this technical result, a screw pile is proposed, which, like the one closest to it, selected as a prototype, includes a tubular barrel and a conical tip with the first (lower) screw blade placed on it. A feature of the proposed utility model that distinguishes it from the known pile 5 adopted as a prototype is that a second (upper) helical blade located at a distance H from the lower blade is placed on the barrel. The distance H is (1.2 - 1.3) the diameter of the upper helical blade DM, which is equal to (3 - 5) the diameter of the barrel dc. The number of turns of each blade is 1.25 - 1.3. The lower screw blade is made with a decrease in diameter by (0.6 - 0.8) of the value of its maximum diameter Ontlah equal to (0.4 - 0.5) VEL - The upper and lower screw blades are made with the same pitch h equal to (0 , 15 - 0.25) Vvl, and the height of the conical tip bk is (2.0 - 2.5) dc. To strengthen the upper and lower blades, or one of them, the screw blades can be equipped with reinforcing pads located on one or both sides of the blade.

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The technical result achieved in the proposed utility model, due to the following. Unlike the prototype, in which there is only one screw blade located on the conical tip, the proposed screw pile has two blades - the upper one located on the tubular shaft and the lower one on the conical tip. Important significant features of the claimed design are the ratio of the geometric parameters of the trunk and the helical blade of the pile. The optimal ratio of these parameters was obtained experimentally from the test results. The lower helical blade is made with a smaller diameter (its maximum diameter is (0.4 - 0.5) Vvl), which provides accelerated immersion of the pile and a decrease in the disturbing force in heavy soils. The reduced diameter of the lower blade significantly facilitates the immersion of piles in heavy clay soils when using the vibration-shock method of immersion. In this case, the upper helical blade, the diameter of which VVL can be selected in the range from 3 to 5 trunk diameters dc, increases the bearing capacity of the pile both for vertical and horizontal loads. An essential sign is that the upper and lower blades are spaced apart by a distance of (1.2 - 1.3) the diameter of the upper helical blade Vvl. From consideration of FIG. It can be seen that when the second turn of the pile blade is turned on, its bearing capacity for compressive load increases by more than 27%. From FIG. 4a it is clear that the bearing capacity of a pile on a horizontal load increases (2 - 2.5) times.

Another significant feature of the claimed pile is that the number of turns of the upper and lower blades is 1.25 - 1.3. The presence of such an overlap leads to the following during the vibration-shock mode. Soil in direct contact with the pile passes into the current state, while the pile begins to sink, and

soil - move along the helical surface of the pile. In the overlap zone, the soil begins to condense, a soil “plug” is formed, resulting in a horizontal reaction applied to the screw blade, which causes some rotation of the pile, then the pile becomes more intense and the process repeats. When removing the pile, a disturbing force is applied vertically upward. In this case, the pile receives vertical upward movements, making some rotation, and the soil moves along the helical surface of the blade, without causing much impact on the blade. The proposed utility model (see p. 2 of the formula) provides for the possibility of reinforcing the upper and lower blades with the help of plates installed on one or both sides. This additional feature significantly increases the strength and reliability of the structure, also contributing to the achievement of the task.

Thus, the combination of the above features allows us to solve the tasks.

Below is described one of the specific examples of the implementation of the proposed utility model.

The utility model is illustrated by drawings, which depict:

figure 1 - the proposed screw pile (General view); FIG. 2 is a plan view of FIG. 1;

in FIG. Figures 3 and 4 present graphs of the results of testing screw piles for compressive load and horizontal load, respectively.

A screw pile consists of a hollow thin-walled cylindrical barrel 1 and a conical tip 2, the height of which bk is 440 mm, which is 2.01 of the trunk diameter dc, which is equal to 219 mm in this particular example. An upper helical blade 3 is welded to the cylindrical barrel 1, the diameter of which is, for example, 850 mm, which

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is 3.9 bore diameter dc. On the pointed conical tip 2, the lower helical flap 4 begins, the maximum diameter of which is located in the dianazone (0.4 - 0.5) Vvl and in this particular case is 340 mm. The blades are made of low alloy or carbon steel sheets with a thickness of 6-8 mm. The distance H between the upper 3 and lower 4 blades is 1020 mm. The upper 3 and lower 4 blades are made with the same pitch h, which is 170 mm, i.e. 0.2 Vvl. The number of turns of each blade is 1.25 1.3, as illustrated in FIG. 2. The turn of the lower blade 4 is made with a gradual narrowing from the maximum diameter, for example, from 340 mm to 240 mm (0.7 Vntlah). To strengthen the upper blade 3, and, if necessary, the lower blade 4, reinforcement plates 5 and 6 are welded to them, the thickness of which is equal to the thickness of the material of the blade.

Immersion of a screw pile is as follows.

A vibratory hammer, for example, MSH-2 is suspended from a boom crane DEK-251 and mounted on the head of a pile. The vibro-mechanism is set to vibration-shock mode and the pile is immersed. At the same time, on average, 4.0 minutes of working time of a vibratory hammer are spent on immersing one pile to a depth of 5 m. It should be noted that when dipping screw piles with screwing, 30 to 50 minutes are spent on each pile. When piles are immersed by the vibro-shock method, they make a complex movement - immersion and rotation. Piles are immersed in the soil due to vibration due to a decrease in soil strength caused by a decrease in internal friction forces acting between the soil particles. As a result, soil particles during mobilization gain greater mobility and the soil, by mechanical properties, becomes a viscous medium. In this case, the immersed pile overcomes both frontal and lateral resistance. Due to the fact that the drag of a screw pile is significantly

more than lateral, it is necessary that the vibromechanism creates a vibro-shock mode. When removing the pile, a disturbing force is applied vertically upward. In this case, the pile is vertical upward movement, while making some rotation, and the dagger moves along the helical surface of the blade, without exerting much influence on it.

Depending on the ground conditions, the screw pile can be immersed in a combined way: first, before introducing the main turn, the pile is immersed with an electric hammer to a depth of 2.5 - 3.0 m, and then the pile is screwed up into syaucha & need.

Thus, the proposed screw pile having the design described above makes it possible to immerse it by the vibration-shock method, while the rate of immersion and extraction of piles by the vibro-method is more than 6 times higher than with conventional screwing. When immersing or removing screw piles, special equipment is not required, since electric vibratory hammers and cranes are widespread equipment.

USED SOURCES:

1.D.D. Barkan. Vibro method in construction. "Gosstroyizdat, M., 1959.

2.Avt.svid. No. 1454909, class E 02 D 5/56, publ. 01/30/89.

3.Avt.svid. No. 1237744, cl. E 02 D 5/56, publ. 06/15/86.

4.Avt.svid. No. 1289963, cl. E 02 D 27/42, publ. 02/15/87.

5.3 Japan Application No. 60-57943, CL E 02 D 5/56, publ. 08/03/94 prototype.

Claims (2)

1. A screw pile comprising a tubular shaft and a tapered tip with a first (lower) screw blade located on it, characterized in that a second (upper) screw blade located at a distance H from the lower blade of 1.2-1 , 3 diameters of the upper helical blade D _VL , equal to 3-5 trunk diameters d _s , while the number of turns of each blade is 1.25-1.3, the lower helical blade is made with a diameter decrease of 0.6-0.8 of its maximum diameter D _NLmax equal (0,4-0,5) D _VL, the upper and lower blade screw Execute step h with the same, equal to (0,15-0,25) D _VL, and the height h of the conical tip _K is (2,0-2,5) d _p. 2. A screw pile according to claim 1, characterized in that the upper and / or lower screw blades are provided with reinforcing pads located on one or both sides.