RU2040677C1 - Bulk material storage - Google Patents

Abstract

FIELD: industrial and agricultural construction. SUBSTANCE: bulk material storage has walls made by built-in members and members mounted in situ and disposed in rows through wall height in mutually spaced relation. Wall members form silo cells made polygonal or round in plan. Silo cells are intersected one with the other so that vertical channels are formed. Wall members have thickened ends and are provided with openings positioned in ends and in joint areas. Openings are adapted for receiving bolts. Wall members are joined so that each of them adjoins with its one end to inner side surface of adjacent member, and with its other end to outer side surface of other adjacent member. EFFECT: increased efficiency and enhanced reliability in operation. 12 dwg

Description

 The invention relates to the construction and can be used in the construction of storage facilities for bulk materials.

 Known storage for bulk materials, including walls of prefabricated elements forming cylindrical or multifaceted silo cells that intersect at the interface with one another with the formation of vertical channels. Prefabricated wall elements are arranged in parallel rows in plan and in height with ligation of vertical butt joints. Each vertical channel is formed from two different types of wall elements from the main element of one of the adjacent cells and an additional element of the other. In this solution, the additional element with both ends adjoins the inner side surface of the main element.

 Due to the intersection of adjacent cells between themselves in plan at the interface with the formation of vertical channels and ligation of vertical butt joints in this design, high strength, stiffness and bearing capacity are achieved. The possibility of using vertical channels as unloading or for active ventilation (aeration) of bulk material determines the good performance of the storage.

 The disadvantages of this solution are the insufficiently high level of assembly and unification of the design, consisting of heterogeneous elements (basic, additional and additional), and the associated increased costs for manufacturing and installation.

 The purpose of the invention is to increase the prefabricated structure, reduce the cost of manufacturing and installation and improve the quality of products by unifying them.

The goal is achieved in that in a storage for bulk materials, including walls of prefabricated elements arranged in rows in height with mutual displacement and forming silo cells intersecting one another with the formation of vertical channels, the walls of each channel are formed by two wall elements of adjacent cells, in pairs docked so that each of them at one end adjoins the inner side surface of the other. In this case, the second end of each prefabricated wall element is adjacent to the outer side surface of the third element, similarly paired with adjacent. In this solution, the walls of each non-vertical vertical channel are formed from the same elements. Silo cells in the plan can be located both in parallel rows, and in cyclically symmetric schemes. In a horizontal projection, they can be hexagonal, octagonal, square or round. In the case of hexagonal cells prefabricated wall element formed three-panel consisting of a middle portion equal in magnitude of the hexagonal cells and two unequal side portions adjoining on the one hand to the middle portion at an angle of ¹²⁰ and having a thickening at the ends, the longitudinal axes of which constitute a the longitudinal axes of the extreme parts are also angles of 120 ^° . On the end thickenings and on the larger of the lateral parts in the place located at a distance from the fold equal to the length of the smaller lateral part, holes are placed.

In the embodiment with silo cells equilateral octagonal side portion three-panel element adjacent to the middle portion at an angle of ^about 135 and the longitudinal axis of the terminal thickenings form with the longitudinal axes of the side portions 90 ^of angles.

 In the case of square silo cells, the wall elements are made of two-pane of larger and smaller parts intersecting at right angles. Most are shorter than the sides of the silo cell by an amount determined by the sum of the length of the smaller part, the thickness of the walls and the width of the two joints. The holes are placed at the ends and at the junction for the most part at a distance from the fold equal to the length of the smaller part.

 With silo cells that are round in plan, the wall elements can be made in two ways outlined around the circumference within a third or a quarter (excluding joints) of its length.

 The proposed solution allows us to form walls of vertical channels from elements, each of which is adjacent to the inner side surface of the other with only one of its ends, to ensure the uniformity of shape and size of wall elements forming each non-contour vertical channel. This allows you to increase the level of prefabrication and unification of the design, reduce the cost of manufacturing and installation and improve the quality of industrial products.

 In FIG. 1 shows a plan for placing wall elements in an even row of storage with hexagonal silo cells; figure 2 is the same in an odd row; in FIG. 3 node I in figure 1; figure 4 three-panel wall element, plan; figure 5 plan for the placement of wall elements in an even row of storage with octagonal silo cells; figure 6 is the same in an odd row; in FIG. 7 plan for the placement of wall elements in an even row of storage with square silo cells; Fig.8 is the same, in an odd row; Fig.9 plan for the placement of wall elements in an even row of storage with round silo cells when performing wall elements with a length of a third of a circle; figure 10 is the same in an odd row; figure 11 plan for the placement of wall elements in an even row of storage with round silo cells when performing wall elements with a length of a quarter of a circle; 12 is the same in an odd row.

 The storage includes walls of prefabricated elements 1 and additional elements 2 arranged in rows in height with mutual mixing and forming silo cells intersecting one another with the formation of vertical channels 3. Elements 1 have thickenings 4 at the ends and holes 5 for bolts 6 at the ends and at the joints and connected so that each of them at one end adjoins the inner side surface of an adjacent element, and the second end to the outer side surface of another adjacent element.

 Elements 1 and 2 are made of reinforced concrete in the factory using traditional methods. The most appropriate height of the wall elements is 1.2 m, the diameter of the circle inscribed in the silo cells is 4-6 m, the wall thickness is 80-160 mm.

 Installation of the storage at the construction site is reduced to the tiered installation of elements 1 and 2 and their connection with each other with bolts 6, passed through holes 5, followed by monoling of the joints.

 In comparison with the prototype, the proposed storage for bulk materials due to the implementation of the walls of the vertical channels of the elements, each of which with only one end adjoins the inner side surface of the other, ensures the uniformity of the shape and size of the wall elements forming each non-vertical vertical channel, and thereby allows to increase the level of assembly and unification of the design, which leads to lower costs for the manufacture and installation and improve the quality of industrial products.

 With square silo cells, the proposed solution also provides improved storage performance due to an increase in the surface suitable for placement of openings for unloading and active ventilation (aeration) of bulk material, due to the possibility of using four sides of each non-contour vertical channel for these purposes. The two-panel shape of the wall elements in this embodiment allows, in addition, to increase their transportability and reduce transportation costs.

 The options with hexagonal silo cells and with round cells when performing wall elements with a third circumference due to the non-parallelism of the rows of cells in plan and their cyclic symmetry, in addition to the above effect common to all options, allow for a more dense arrangement of cells, thereby reducing the total the perimeter of the walls and thereby reduce the material consumption of the structure and improve the use of the area allocated for storage.

Claims (1)

 STORAGE FOR BULK MATERIALS, including silo cells intersecting with the formation of vertical channels, the walls of which are formed by arranged rows in height with mutual displacement of elements with adjacent ends of elements located outside the storage contour to the outer and inner side surfaces of adjacent elements, characterized in that each located outside the contour of the storage element is adjacent at one end to the inner side surface of an adjacent element, and at the other end to the outer side surface Gogo adjacent element.

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