RU46773U1 - COMPLEX OF TECHNOLOGICAL EQUIPMENT FOR CONSTRUCTION OF HYDROTECHNICAL STRUCTURE - Google Patents

Abstract

Usage: devices for carrying out work in hydraulic engineering for the construction of approach racks, transshipment complexes and berthing facilities.

Essence: the creation of a technological complex for the construction of a hydraulic structure using a remote conductor of a special design for the installation of pile supports and subsequent sequential installation of spans.

Effect: reduce construction time, reduce the load on the crane and the complexity of the work while simplifying the process of erecting a hydraulic structure, increasing reliability and the possibility of uninterrupted operation regardless of weather conditions and disturbance in the water area.

Description

The technical solution relates to devices for carrying out work in hydraulic engineering construction and can be used for the construction of approach racks, transshipment complexes and berthing facilities.

The erected hydraulic structure traditionally includes [5-7] pile supports with a grillage installed on them.

Typical analogs of complexes for the construction of hydraulic structures are devices [2,3], which modify traditional structural designs [4-7]. The device [3] contains a working platform with equipment for concrete work and a set of means for the construction of a berthing structure, including pile supports with a grill installed on them. Moreover, in the device [3] the working platform is made on the floating base of the watercraft (pontoon) with subsequent transportation of products (piles, columns, grillage slabs) by this watercraft to the installation site, which is carried out using hoisting-and-transport mechanisms on this watercraft.

The disadvantage of the device [3] are the complexity, complexity and high capital costs associated with the use of boats. Dependence on weather conditions (wave mode) cannot, in a number of cases, ensure the planned construction time, and the use of a number of

floating in shallow water is very difficult. The disadvantages of the installation [3] make it difficult to achieve the optimal production criterion of “complexity-cost-efficiency”, i.e. achieving the maximum possible efficiency (reducing the time of work, reducing the complexity and material consumption) with acceptable complexity and cost.

The complex [2] for the construction of a berthing structure allows you to abandon the use of complex, expensive and inapplicable in the conditions of significant waves of watercraft for work and transportation of building elements and to mount a hydraulic structure with a section-wise grillage by successive sliding slabs.

The complex [2] contains a working platform with equipment for concrete work and a set of means for the construction of a berthing structure (PS), including pile supports with a grillage installed on them. The working platform of the complex [2] is made in the form of a longitudinal horizontal slipway located on land near the shoreline, equipped with equipment for the production of PS grill slabs. The set of means for the construction of substations includes lifting devices, an installation for mounting pile supports of the base of the substation, jacking devices for sequential horizontal movement of plates along the supporting guide limiters with the possibility of section-by-stage extension of the grill of the substation and the module for final installation work. The slipway is made in the form of a reinforced concrete slab with a metal upper plane and is equipped with slots for securing the jack stops. The equipment of the slipway is made with the possibility of producing reinforced concrete slabs with a metal lower base and holes for installation on pile supports. The set of means for the construction of the substation is placed on the slipway with the ability to move to the installed slabs grill PS, sequential

pushed along the supporting guide restraints on the pile supports of the base of the substation using jacking devices.

However, in some cases, the technology [2] of successively pushed slabs along supporting guide stops on pile supports installed in previously drilled wells for them cannot satisfy the complex requirements for reducing installation time while reducing its complexity due to relative complexity and the need for auxiliary operations ( drilling holes under piles, installing jacks, manufacturing plates of a special design) and depending on weather conditions and wave conditions.

The technological complex [1] for the construction of a hydraulic structure (GTS), adopted as a prototype, contains a working platform, a set of means for constructing a hydraulic structure, including pile supports with a grill of slabs installed on them, and the working platform is made in the form of a longitudinal horizontal slipway equipped with equipment and prefabricated elements for the installation of hydraulic structures, and the totality of means for the construction of hydraulic structures includes a lifting device and installation for the installation of pile supports of the base of hydraulic structures with sectional expansion span GTS grillage and module for final installation work. The lifting device is made in the form of a heavy crane, the installation for mounting the pile supports includes a conductor frame set horizontally on the design axis along the span along the length and width of the span with an external conductor mounted on it, one end of which is mounted on the transverse metal crossbar of the already installed hydraulic span, and the second remote end is mounted on two pairs of support posts equipped with hydraulic drives, the first pair of which is mounted vertically on the bottom soil, and the stands of the second pair are installed veins are inclined at an angle of 15-25 ° to vertical racks. At the same time, the conductor is equipped with openings made in the form of glasses for placing pile supports at the design position by means of a crane with

their subsequent immersion in the bottom soil with a driven projectile to the required depth and fixing with stops located in the openings of the conductor. A transverse metal crossbar mounted by a crane and secured by a welded joint is mounted on the upper ends of the pile supports, and metal orthotropic plates are installed and fixed by a welded joint on the transverse crossbars of the hydraulic structures. A crane and prefabricated elements for installation of hydraulic structures, including pile supports made in the form of large-diameter metal pipes, metal cross beams and orthotropic plates welded from metal sheets, as well as other equipment, including a hammer for driving pile supports on required depth. A hydraulic hammer, or a vibro-driver, or another driving device, moved from one pile support to another by means of a crane, was used as a driven-in projectile for driving the pile supports of the GTS.

The main disadvantage of the technological complex [1] is that, as the grillage spans increase with increasing water area during the construction of hydraulic structures, more powerful (and, accordingly, heavier) support racks are required, which necessitates the use of a crane with a higher carrying capacity than at the initial stage of construction , which limits the capabilities of the complex [1]. In addition, the inclined support tubular racks to increase the stability of the structure, it is desirable to place in plan at a certain angle to the remote end of the conductor frame from its outer side.

The essence of the proposed technical solution is to create a set of technological equipment for the construction of hydraulic structures using the same crane (crane of one lifting capacity) for installing a remote (exposed) conductor with support columns and subsequent sequential installation of spans on pile supports.

The main technical result of the proposed complex is to reduce the load on the crane when installing vertical and inclined racks on which the conductor frame is mounted, and, as a result, expand the functionality through the use of the same crane with a given lifting capacity with increasing depth of the water area. This reduces the complexity of the work while simplifying the process of erecting hydraulic structures. In addition, the proposed complex provides increased stability and reliability of installation of hydraulic structures due to the rational relative position of the vertical and inclined support racks of the conductor frame.

The technical result is achieved as follows. The complex of technological equipment for the construction of a hydraulic structure (GTS) contains a working platform and a set of means for the construction of a hydraulic structure, including pile supports buried in the ground of the bottom of the water area with a grill of slabs installed on them, and the working platform is made in the form of a horizontal horizontal slipway equipped with prefabricated installation of hydraulic structures, and the totality of means for constructing hydraulic structures includes a lifting device in the form of a heavy crane and an installation for mounting pile supports founding of hydraulic structures with step-by-step increase in spans of the hydraulic structures grid. At the same time, the installation for mounting pile supports includes a conductor frame set horizontally on the design axis along the span along the span and with a remote conductor mounted on it, one end of which is mounted on the transverse metal crossbar of the GTS span already mounted, and the second remote end is installed, at least two pairs of support posts equipped with hydraulic drives, the first pair of which are mounted vertically on the bottom soil and rests on the support platforms located on the bottom, and the supports of the second pair are tilted obliquely at an angle of 15–25 ° to vertical posts with a slight penetration into the bottom soil. Conductor

it is equipped with openings made in the form of glasses for placing pile supports at the design position by means of a crane and then immersing them in the bottom soil with a driven projectile to the required depth and fixing the stops located in the openings of the conductor. A transverse metal crossbar mounted by a crane and secured by a welded joint is mounted on the upper ends of the bottom of the pile supports buried in the ground, and metal orthotropic plates are mounted and secured by a welded joint on the transverse crossbars of the GTS sections.

A distinctive feature of the complex is that the vertical and inclined supporting tubular posts are muffled from the lower ends and have a diameter d and linear weight P, which, due to the buoyancy force, provide the specified compensation M of the load on the crane in accordance with the expression

M = l [P (n _in + n _n ) -0.785 d ² (n _in + n _n seca)], (1)

where M is the load compensation on the crane, kgf;

l is the depth (vertical) of immersion in the water part of the support tubular racks, m;

P is the linear weight of the supporting tubular posts, kgf / m;

n _in , n _n - the number of vertical and inclined support tubular racks, respectively;

0.785d ² - buoyancy force, kgf normalized to l = 1 m of the support column;

d is the diameter of the support legs, m;

α is the angle of inclination to the vertical of the inclined support legs. The complex is also characterized in that the inclined support tubular posts placed at an angle a to the vertical posts are placed in plan at an angle β from 0 ° to 60 ° to the remote end of the conductor frame from its outer side.

In addition, the complex is distinguished by the fact that a crane and prefabricated elements for installation of hydraulic structures are placed on the working site, including pile supports made in the form of large diameter metal pipes, metal cross beams and orthotropic plates welded from metal sheets, as well as other equipment, including driven hammer for driving pile supports to the required depth, which is used as a hydraulic hammer, or a vibratory driver, or another driving device, moved from one pile bearing to another th crane.

The difference of the complex is also that the conductor frame is equipped with flooring and fencing and is equipped with a technological platform for installation work.

In specific cases of the complex implementation, the crane and the installation for the installation of hydraulic structures are made with the possibility of sequential sectional growth of spans of the grillage by moving the crane on the installed slabs of the next span to expose the conductor frame with the conductor to the design position of the next span of a straight or performed with branches of the hydraulic structure.

The drawing shows a General diagram of the design of the complex for the construction of hydraulic structures.

The GTS construction complex contains a working platform 1, pile supports 2, grillage 3, orthotropic plates 4, a crane 5, a conductor frame 6, a conductor 7, crossbars 8, vertical supporting racks 9 with supporting platforms 10, inclined supporting racks 11, openings 12 conductor, flooring 13, fencing 14, technological platform 15.

The operation of the complex for the construction of hydraulic structures is illustrated by the following example (see drawing).

On the working platform 1, the grillage 3 contains the crane 5 used in the construction of the GTS and prefabricated elements: pile supports 2,

made in the form of metal pipes of large diameter, metal cross beams 8 and orthotropic (direct-directed) plates 4, as well as other equipment (not shown in the drawing), including a driven projectile for driving pile supports to the required depth. The crane 5 exposes the conductor frame 6 with the external conductor mounted on it 7. The conductor frame 6 and the conductor 7 are aligned horizontally on the design axes along the length and span of the mortar 3, while one end of the conductor frame 6 is mounted on the transverse metal crossbar 8 a mounted span of the hydraulic structures, and the second remote end of the frame 6 is mounted on two pairs of support posts 9 and 11 equipped with hydraulic drives. A pair of support posts 9 is mounted vertically on the bottom ground on the support platforms 10, and about the porous racks 11 are mounted obliquely at an angle of 15-25 ° to the vertical racks 9 to prevent lateral wave and wind effects on the frame 6 and the conductor 7. At the same time, to increase the stability of the mounted structure, the inclined support racks 11 placed at an angle a from 15 to 25 ° to the uprights 9, placed in plan at an angle β from 0 ° to 60 ° (preferably 30-45 °) to the remote end of the conductor frame from its outer side.

Since the vertical and inclined support posts 9 and 11 are muffled from the lower ends, when the posts 9 and 11 are immersed in water, a force pushing them out is created in accordance with expression (1), which compensates for part of the load on the crane 5, which allows the use of a crane of the same carrying capacity. So with an increase in the depth of the water area to l = 12 m for four tubular racks (two vertical and two inclined: n _in = n _n = 2) with a diameter of d = 630 mm and a linear weight of P = 153 kgf / m, the total weight of the supports is 7.3 t, and the corresponding compensation M of the load on the crane (in accordance with expression (1) with α = 0) will be about 7.7 t. Thus, the muffled support legs 9 and 11, according

essentially, they play the role of vertical and inclined pontoons, creating buoyancy for the erected structure.

Pile supports 2 are fed into the openings 12 of the conductor 7 by the crane 5, which are installed at the design position and then immersed in the bottom soil to the desired depth with a driven projectile, followed by fixing with stops placed in the openings 12 of the conductor 7. As a driven projectile for driving the pile supports 2 a hydraulic hammer, or a vibratory driver, or another driving device, moved from one pile support 2 to another by means of a crane 5, can be used.

Then, with the help of a crane 5, a crossbar 8 is started on piles 2 with local adjustment and welding of the crossbar 8 and piles 2. Welding is carried out from the flooring 13 of the technological platform 15, which has a protective fence 14.

Then, on the transverse crossbars 8 of the already mounted and newly mounted sections, the GTS grillage 3 are installed and welded with orthotropic plates 4. After the installation of the next section (span) is completed, the grill 3 of the crane 5 is moved to the installed plates 4 to move the frame 6 with the conductor 7 to the new design position, thereby implementing a sequential section-by-stage escalation of spans of the grillage 3 of a straight-line or performed with branches of the hydraulic structures.

Thus, by means of a special-purpose remote conductor for installing pile supports and using muffled from the lower ends of the support posts, the load on the crane is reduced and, accordingly, the labor intensity of the work is reduced while simplifying the process of constructing the hydraulic structures, the reliability of the installation of hydraulic structures is increased, and the possibility of uninterrupted operation regardless of weather conditions and unrest in the water.

BACKGROUND OF THE INVENTION

I. Prototype and analogues:

1. RU 41032 U1, 10.10.2004 (prototype).

2. RU 18405 U1, 06.20.2001 (analogue).

3. RU 2098558 C1, 12/10/1997 (analogue).

II. Additional sources of prior art:

4. SU 1629369 A1, 04/10/1991.

5. Nikerov P.S., Yakovlev P.I. Seaports. - M: Transport, 1987, 416 p. (P.118-274).

6. Ambaryan O.A., Goryunov B.F., Belinskaya L.N. The device of seaports. - M.: Transport, 1987, 272 p. (P. 122 - 199).

7. Berthing facilities. - In the book. "Marine Encyclopedic Reference: In 2 volumes. Volume 2 / Ed. N.N. Isanina. -L.: Shipbuilding, 1987, 520 p. (P. 134- 136).

8. SU 1388515 A1.15.04.1988.

9. SU 1799411 A1.28.02.1993.

Claims (5)

1. A complex of technological equipment for the construction of a hydraulic structure (GTS), containing a working platform and a set of tools for the construction of hydraulic structures, including pile supports buried in the soil of the bottom of the water area with a grill of slabs installed on them, and the working platform is made in the form of a horizontal horizontal slipway equipped prefabricated elements for the installation of hydraulic structures, and a set of means for the construction of hydraulic structures includes a lifting device in the form of a heavy crane and an installation for mounting pile supports of the GTS base with section-wise extension of the spans of the GTS grillage, while the installation for mounting pile supports includes a conductor frame set horizontally on the design axis along the span and the span mounted on it with a remote conductor, one end of which is mounted on a transverse metal crossbar of an already mounted GTS span, and the second remote end is installed on at least two pairs of support posts equipped with hydraulic drives, the first pair of which is installed vertically on the bottom soil and it is supported by the supporting platforms located at the bottom, and the racks of the second pair are installed obliquely at an angle of 15 - 25 ° to the vertical racks with a small penetration into the soil of the bottom, the conductor is equipped with openings made in the form of glasses for placing pile supports to the design position by means of a crane with subsequent immersion them into the bottom soil with a driven projectile to the required depth and fixing with stops placed in the conductor openings, a transverse metal rig mounted on the upper ends of the bottom of the pile supports bottomed in the ground b, mounted by a crane and secured by a welded joint, and metal orthotropic plates installed and secured by welded joint on the transverse crossbars of the already mounted and assembled GTS sections, characterized in that the vertical and inclined supporting tubular posts are muffled from the lower ends and have a diameter d and linear weight P, providing due to the buoyancy force the specified compensation M of the load on the crane in accordance with the expression M = l [P (n _in + n _n ) -0.785d ² (n _in + n _n secα)], where M is the load compensation on the crane, kgf; l is the depth (vertical) of immersion in the water part of the support tubular racks, m; P is the linear weight of the supporting tubular posts, kgf / m; n _in , n _n - the number of vertical and inclined support tubular racks, respectively; 0.785d ² - buoyancy force, kgf normalized to l = 1 m of the support column; d is the diameter of the support legs, m; α is the angle of inclination to the vertical of the inclined support legs. 2. The complex for the construction of hydraulic structures according to claim 1, characterized in that the inclined support tubular racks placed at an angle α to the vertical racks are placed in plan at an angle β from 0 ° to 60 ° to the remote end of the conductor frame from its outer side. 3. The complex for the construction of hydraulic structures according to claim 1, characterized in that the crane and prefabricated elements for installing hydraulic structures, including pile supports made in the form of large diameter metal pipes, metal crossbars and orthotropic plates, welded from metal, are placed on the working site sheets, as well as other equipment, including a driven-in projectile for driving pile supports to the required depth, which is used as a hydraulic hammer, or a vibrator, or other driving device, moved from one pile support to the other by means of a crane. 4. The complex for the construction of hydraulic structures according to claim 1, characterized in that the conductor frame is equipped with flooring and fencing and is equipped with a technological platform for installation work. 5. The complex for the construction of hydraulic structures according to claim 1, characterized in that the crane and installation for the installation of hydraulic structures are made with the possibility of sequential sectional expansion of spans of the grillage by moving the crane to the installed slabs of the next span to expose the conductor frame with the conductor to the design position of the next span straightforward or performed with branches of the GTS.