RU2123091C1 - Foundation for metal column, method of foundation construction and alignment - Google Patents

Abstract

FIELD: metalwork, mainly, frames of production buildings. SUBSTANCE: foundation is hollow conical reinforced concrete structure filled with crushed stone. Reinforced concrete foundation passes into steel internal conical shell oriented with its small base upward. Fitted on this conical shell from atop is external shell of column. Wide bases of shells have flanges. Accommodated in one of flanges are teeth-retainers, while the other flange has mating holes. Contacting surfaces of flanges are milled. Welded to internal surface of conical shell are longitudinal reinforcing bars at an angle of 35-45 deg to column longitudinal axis. Longitudinal bars are embraced by circular rods with spacing of 100-400 mm. Fastened to reinforcing cage are branch pipes. Column is mounted without adjustment. During lowering of column downward teeth-retainers are aligned with retaining holes and column is secured in design position with gap between flanges closed. In case of nonuniform sagging of building columns, they are aligned as follows. Connected to branch pipes are hoses from concrete pump and plastic mortar is pumped to branch pipes under pressure. Mortar forces out the reinforced concrete holder to jack the column through the required value. In case of nonuniform jacking, respective part of foundation is loaded with counterweight. EFFECT: reduced specific material consumption; higher reliability of foundation and joint unit of column with foundation; reduced labor input in building frame alignment. 3 cl, 3 dwg

Description

 The invention relates to metal structures, mainly frames of industrial buildings.

 Known hollow conical reinforced concrete foundation (and.with. N 83768, class E 02 D 27/52, 1977). There is also a method of leveling the foundation (A.S. N 1335657, class E 04 B 1/02, 1987). We will take these decisions as a prototype. The disadvantage of the prototype is the increased complexity of manufacturing, installation and straightening.

 The purpose of the invention is the reduction of material consumption, and increasing the reliability of the foundation and the connection node of the column with the foundation, and reducing the complexity of straightening the frame.

The goal is achieved in that the metal column is connected to the foundation by means of two conical metal shells that fit tightly into each other, with a length of 1.2-1.5 column heights with the same slope forming to the column axis (2-3 ^o ), equipped with milled flanges , in one of which fixing teeth are fixed, and in the other holes are made, the outer conical shell connected to the column with a smaller base, and the inner large base with the foundation by means of longitudinal reinforcing bars bent at an angle m 15-45 ^o to the axis of the column, covered by annular rods and forming a reinforcing cone expanding downward, which is the reinforcing cage of a hollow reinforced concrete conical foundation, the cavity of which is filled with bulk material, resting on a soil base.

A method of constructing a foundation for a metal column includes making a foundation with a cavity, connecting it to the column, making a geodetic breakdown of the location of the foundation, placing it in the design position, and filling the cavity with material that rests on the ground. To do this, conical metal shells tightly sinking into each other are made, flanges with holes are welded, one of which is equipped with locking teeth, the outer conical shell is welded according to the template with a small base to the column, and longitudinal reinforcing rods are bent to the inner shell from the larger base, bent 14-45 ^o angle to the column axis, the longitudinal rods comprise annular rods 100-400 mm in increments of forming the reinforcing frame, operate on the center of each cone column of crushed stone, put on pos a single reinforcing cone together with a steel inner conical shell at the apex, securing a nozzle to the reinforcing cage, putting the formwork on top and temporarily connecting it to the reinforcing cage, installing a conductor and leveling the reinforcing cage with the inner shell and formwork, fixing them in the design position, introducing the concrete pump hose into the neck of the inner shell and the conical foundation is concreted with vibration, and after setting the concrete without adjustment, the metal column is mounted, putting on top of a hundred the outer outer conical shell of the column on the inner shell of the foundation, combining the locking teeth with the holes in the flange and tighten the friction studs of the flanges.

 Thus, a hollow conical foundation is formed, the cavity of which is filled with crushed stone, and a conical shell is placed at the top of it and a column is calibrated without assembly.

 Filling the cavity with crushed stone ensures maximum roughness in the area of its contact with the reinforced concrete hollow foundation and helps to reduce the forces in the ring reinforcement of the foundation. In order to reduce efforts in annular reinforcement, the bottom end of the foundation is made perpendicular to its generatrix.

The leveling of the foundation is carried out either after the manufacture of foundations (with poor-quality performance of work), or after the building has been used for some time and uneven settlement of the columns. Straightening is performed in the following sequence. In the first case, the finished conical foundations are leveled and foundations made below the design elevation are identified, and the necessary straightening values for height Δ _{in the} individual foundations are determined.

 For straightening, sand mortar or sand pulp with the addition of a plasticizer, such as clay, is used. The channel is cleaned in the pipe 10 and in the adjacent layer of crushed stone filling. Concrete is destroyed by drilling or breakdown using a jackhammer and a special pointed punch of the required length.

 To reduce labor costs later, when straightening the entire frame of the building after operation and uneven settlement of the columns, it is rational to clean the nozzles 10 1-2 hours after concreting, i.e. when concrete has not yet gained strength.

A hose is connected to the pipe 10 and a plastic pulp is forcedly pumped into the crushed stone backfill, which fills all the voids in the crushed stone and jacks up the foundation by the required amount. Lifting power can be created so that raises a building of any mass. So, for example, with an excess pressure of 1 atm pulp, a lifting force of 10 t / m ^{2 is created} , i.e. with a foundation area of 10 m ^{2, the} lifting force on each of the straightened columns will be 100 tons.

 Therefore, in the second case, when the frame of the entire unevenly settled building is frayed, there is no need to dig out the foundations as a whole. Only the pipe 10 of the foundation is dug up, which is arranged in the upper part of the foundation and can even be brought inside the workshop.

 In this case, excavation is not carried out, since the pulp pressure is enough to overcome not only the mass of the building, but also the mass of soil filling the sinuses of the foundation.

 In FIG. 1 shows a developed foundation in section; in FIG. 2 - node pairing columns with the foundation in the Assembly; in FIG. 3 - view A.

 The reinforced concrete hollow conical foundation 1 is filled with bulk material 2, for example, crushed stone or slag. Reinforced concrete foundation 1 passes into a steel inner conical shell 3, oriented upward. A conical shell 4 of the column is mounted on top of it, oriented downward by the nozzle.

 The wide bases of the inner 3 and outer 4 shells are provided with flanges 6, in one of which are placed the locking teeth 7, and in the other mating holes. The contacting surfaces of the flanges are milled.

To the inner surface of the tip 3 longitudinal reinforcing rods 8 are welded, bent at an angle of 30-45 ^o to the longitudinal axis of the column. Longitudinal rods 8 are covered by annular rods 9 with a pitch of 100-400 mm. A pipe 10 is attached to the reinforcing cage.

 In order to reduce the consumption of cement and reinforcement, the conical foundation 1 is concreted in layers with a gradual increase in the grade of concrete, that is, the top layer is the most durable. On the reinforcing conical frame, a nozzle 7 is fixed for pumping concrete.

 After installing the formwork and connecting it to the conical frame and the inner conical shell 3, the spatial alignment of the assembled structure as a whole is carried out by means of a conductor (not shown) and fixing it in the design position.

 Non-alignment installation of the column is carried out after hardening of concrete and dismantling of the conductor, and formwork, and filling the sinuses of the foundation as follows. When lowering the column from top to bottom, the fixing teeth are combined with the fixing holes and, when the gap is closed, the column is fixed in the design position with friction studs of the flanges.

 After the column is installed, the space between the flanges and the top of the foundation is filled with concrete in order to transfer part of the compressive forces to the foundation concrete directly, which ensures the unloading of the inner conical shell and conical frames. At the same time, the bottom of the column is protected against corrosion.

 In operation, the foundation of the column operates as follows. The compressive force is transmitted through the milled end of the flange to the outer shell 4, to the inner shell 3, then to the reinforced concrete conical foundation, then to the crushed stone backfill and distributed along the sole of the entire foundation to the soil base.

 In case of uneven settlement of the building columns, their straightening is carried out as follows: hoses from the concrete pump are connected to the nozzles 10 and plastic pulp is pumped into them, for example, from sand with the addition of a plasticizer. The pulp squeezes the reinforced concrete foundation and due to this the column is jacked up to the required size.

 In case of uneven jacking, the corresponding part of the foundation is loaded with a counterweight.

The economic effect arises due to the following:
1. Reduced metal consumption by 10-15%.

 2. Reduced concrete consumption by 20-30%.

 3. Reduced the complexity of manufacturing and installation of the foundation.

 4. Ensured straightening of the foundation to restore normal operation of the building with uneven settlement of columns.

Claims (3)

1. The base for a metal column, including material filling the base cavity expanding towards the bottom and supported on the ground, and flanges for connecting the foundation to the column, in one of which holes are made, characterized in that the foundation for connecting to the column is equipped with two conical metal shells , one of which is connected to the column with a smaller base, and is tightly worn on the other, connected to the foundation, and the conical metal shells have a length of 1.2 - 1.5 the height of the cross section of the column with a slope forming to vertical 2 - 3 ^o , the flanges are milled and fixed on the conical metal shells, and one of them is equipped with locking teeth, while the foundation is made in the form of a conical reinforced concrete cage with a reinforcing cage, the longitudinal rods of which are welded to the conical metal shell of the foundation at an angle of 15 - 45 ^o to the axis of the column and covered by ring rods with the formation of a cone expanding downward, and crushed stone was used as the material filling the foundation cavity. 2. A method of constructing a foundation under a metal column, including making a foundation with a cavity, connecting it to the column, making a geodetic breakdown of the location of the foundation, placing it in the design position and filling the cavity with material that rests on the ground, characterized in that it is tightly sunken in each other conical metal shells of another - welded to their wide base milled flanges, one of which has holes, and the other - holes and fixing teeth, after which it is welded the outer shell to the column is wound according to the template with a narrow base, and longitudinal reinforcing bars are welded from the inside to the inner shell, bent them outward at an angle of 15 - 45 ^o to the axis of the column and cover them with ring rods with a pitch of 100 - 400 mm, forming a conical basement frame, and after a geodetic breakdown of the location of the foundation in the center of the column on the ground, a cone is made of crushed stone filling the foundation cavity, a conical frame is put on it together with a metal shell at the top, and it is fixed to the conical frame se branch pipe, put on a cone formwork on top, temporarily connect it to a metal shell, install a conductor, straighten the cone shell in space together with the cone frame and formwork, fix them in the design position, connect the concrete pump hose and concave the cone base of the foundation, then after setting a concrete column is mounted on a concrete column by putting on top the outer conical shell on the inner one to connect the column to the foundation by combining the fixing teeth -stand from the flange with holes, and tightening of the other flange high studs in the flanges.  3. The method of straightening the foundation under a metal column, including raising a portion of the foundation by the required amount, characterized in that the foundation is made in the form of a reinforced concrete shell, the cavity of which is filled with crushed stone with its support on the ground, and when concreting the reinforced concrete shell, a pipe is used that is left in the foundation body and with uneven settlement of the column, connect the concrete pump hose to the nozzle and pump a plastic solution into the cavity of the reinforced concrete shell, which fill the voids in the rubble and poured reinforced concrete shell by the required amount.

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