RU116564U1 - TOWER TYPE DRILL RIG - Google Patents

Abstract

1. A tower-type drilling rig, including a volumetric one-piece module containing a crown block, volumetric sections containing a bar grid forming the edges of the tower, and support elements connected in height to form support columns, while the volumetric sections consist of lower sections made in the form Tower "legs", rectangular sections forming vertical edges, and a trapezoidal section forming inclined edges; the rod lattice of rectangular sections and a trapezoidal section form trusses with horizontal chords, in each of these sections the trusses are grouped in two on each face and the truss chords are attached to the corresponding supporting elements, and the adjacent horizontal truss chords are interconnected; the volumetric one-piece module is formed by the upper section, which includes vertical support elements on which the crown block frame is installed, and the support elements of the upper section are connected to the corresponding support elements of the trapezoidal section. ! 2. The drilling rig according to claim 1, characterized in that it is provided with an additional section installed between the trapezoidal section and the upper section. ! 3. An oil rig according to claim 1, characterized in that the supporting elements are connected by means of a detachable connection, for example a finger connection. ! 4. The drilling rig according to claim 1, characterized in that in each rectangular and trapezoidal sections, horizontal truss chords are connected to the supporting elements by means of a detachable connection, for example a finger connection. ! 5. The drilling rig according to claim 1, characterized in that adjacent horizontal chords of the grouped trusses are connected in height by means of a split

Description

The utility model relates to the equipment of drilling rigs for various purposes, including for offshore and cluster drilling rigs.

A known construction of a tower derrick for offshore drilling rigs from the description to utility model CN No. 2013133219 (selected as the closest analogue). The drilling rig is made of eleven volumetric sections and a crown block; volume sections contain a rod grating connected with support elements connected in height to form tower support columns. Volumetric sections are made in the form of two lower sections, representing the "legs" of the tower, three rectangular sections and six trapezoidal sections, and the trapezoidal sections are made of different heights. The lower and rectangular sections form vertical faces, and the trapezoid sections form the inclined faces of the tower.

The crown block will hold the frame with the equipment installed on it (pulley sections, auxiliary pulleys), the crown block frame is mounted on the inclined support columns of the trapezoidal upper section.

The use in the well-known tower of a complex triangular pattern of a lattice with many bonds having different lengths characterizes a low level of unification of the structure of such a tower, in other words, indicates a significant nomenclature of elements.

In addition, to ensure the angle of inclination of the respective faces of the tower, six trapezoid sections are made of different heights, therefore, the support columns in these sections also have different lengths. This also indicates an increase in the range of elements of the tower.

In addition, with the height of the sections exceeding the transport dimension, the tower structure involves the assembly of a large number of elements of each section (support columns, braces, horizontal ties) directly on the installation site, which indicates the complexity of installation work.

The problem solved when using the utility model is to simplify the installation of the derrick due to the maximum unification of the elements while increasing its stability.

The problem is solved in that the tower derrick, including a volumetric one-piece module containing a crown block, volumetric sections containing a rod grate forming the facets of the tower, and support elements connected in height to form support columns, while volumetric sections consist of lower sections made in the form of "legs" of the tower, rectangular sections forming vertical faces, and a trapezoid section forming inclined faces; trusses of horizontal sections and a trapezoidal section are formed by trusses with horizontal belts, in each of the truss sections indicated two on each face are grouped and truss belts are attached to the corresponding supporting elements, and adjacent horizontal truss belts are interconnected; the volume one-piece module is formed by the upper section, including vertical supporting elements on which the crown block frame is mounted, and the supporting elements of the upper section are connected with the corresponding supporting elements of the trapezoid section.

The inventive utility model is equipped with an additional section mounted between the trapezoidal section and the upper section.

In the claimed utility model, the supporting elements are connected by means of a detachable connection, for example, a finger connection.

In the claimed utility model, in each rectangular and trapezoidal sections, horizontal truss belts are attached to the supporting elements by means of a detachable connection, for example, a finger connection.

In the claimed utility model, adjacent horizontal zones of grouped trusses are connected in height by means of a detachable connection, for example, a finger connection.

In the claimed utility model, the elements of the core lattice of the lower sections are connected by means of a detachable connection, for example, a finger connection.

In the claimed utility model, the axis of the finger connection is connected to the elements of the rod lattice using a flexible connection, for example, in the form of a chain.

In the claimed utility model, the core lattice of the tower is made of metal products with an angular profile, and the supporting elements are made of metal products with a tubular round profile.

In the claimed utility model, the volumetric sections are provided with a shelter made of soft panels. At the same time, the trusses are equipped with means for attaching the tower soft shelter made in the form of metal loops intended for threading the soft shelter cord, while metal loops are fixed on horizontal belts and extreme racks of the truss core lattice.

The essence of the utility model is explained as follows.

To simplify the installation of a tower derrick, the volumetric sections forming the vertical and inclined faces of the derrick (with the exception of the lower sections, which are the "legs" of the derrick) are made using trusses, which are factory-ready mounting units. The availability of ready-made trusses eliminates the need for assembly operations for each connection of the tower grate directly at the installation site.

Farms are flat metal structures with horizontal belts connected by rod ties to form a triangular lattice.

In the rectangular sections of the tower, trusses are used that are identical in size and the “pattern” of the grill; in the trapezoid section of the truss, they can be identical only by one criterion: in height, which is an obvious fact.

The trapezoidal and each of the rectangular sections of the tower contain support columns to which trusses are attached, grouped in two on each face of the tower. The feasibility of combining two farms in one such section on each side is explained by the optimal combination of farm sizes and tower section sizes. Moreover, the size of the trusses, as well as the dimensions of the elements of the supporting columns, are interconnected with a permissible value of the transport dimension of 3250 mm.

The horizontal truss belts are attached to the supporting elements of each rectangular and trapezoid sections. Therefore, the height of each support element of such a section contains four attachment points, this means that the flexibility of the support element is reduced, because when calculating flexibility, not the entire length of the support element is taken into account, but its fourth part. Thus, the implementation of the core lattice of faces from farms (except for the lower sections) leads to increased stability of the support columns of the tower.

The detachable connection of support elements with horizontal truss belts is made of the need for multiple mounting / dismounting of the tower.

Grouped trusses, two on each side of the rectangular and trapezoid sections, are connected, and the connection is made connecting adjacent truss belts (i.e., the upper belt of the lower section is connected with the lower belt of the upper section). Communication farms made in the form of a detachable connection, for example, finger.

In addition, the support elements of the sections forming the support columns of the tower and the elements of the core lattice of the lower sections forming the "legs" of the tower are fastened in a detachable connection.

Thus, when using the inventive tower all connections and communications are made detachable, it is advisable from the point of view of ensuring multiple installation / dismantling of the tower. The use of a finger joint as a detachable joint reduces assembly time of the tower and simplifies installation compared to, for example, the bolted joint of the corresponding elements. So, for example, one node connecting the supporting elements may contain up to six bolts.

The advantage of a finger joint is an increased service life compared to the service life of bolts and nuts, as when dismantling the elements of the tower to extract the latter during impact, the thread is destroyed.

The use of a finger joint leads to a reduction in the installation time of the tower due to the fact that the axis is made with a shoulder (means of connection) and is connected by a flexible connection to the element of the core lattice or to the supporting element of the tower, being near the attachment point. Such a connection can be performed, for example, in the form of a chain. The fastening of the axes (means of connection) by flexible coupling to the above elements of the tower can be performed in the factory, which also positively affects the convenience and reduction of the installation time of the tower.

The use of at least one trapezoidal section in the design of the claimed drilling rig is explained by the desire for maximum unification of the tower elements due to the use of identical assembly units of factory readiness. As indicated above, it is the rectangular sections that can contain identical trusses in size and pattern of the lattice.

A preferred use of the claimed utility model is that the tower may be provided with an additional trapezoidal section mounted between the trapezoidal section and the upper section. An additional trapezoidal section is made with inclined support elements that are connected to the rod elements made in the form of braces, i.e. additional trapezoidal section is made without the use of trusses. This is due to the fact that the use of trusses in the upper trapezoidal section will lead to an increase in the nomenclature of truss elements, which contradicts the task.

The presence of a three-dimensional integral module, made in the form of the upper section of the tower and the equipment of the crown block, makes it possible to perform the specified module in the factory. Therefore, at the installation site of the tower there is no need to install a frame with the appropriate equipment on the supports of the upper section. The implementation of the upper section of the tower with vertical support columns is a prerequisite for the possibility of installing a crown block frame on them, therefore, to form a prismatic volume module that is optimal for transportation. The dimensions of the volume one-piece module are selected from the condition of the possibility of its delivery by transport.

Thus, the principle of unification, formulated as a reduction to a single form or system, is provided when using the claimed utility model due to the fact that the volumetric sections of the tower are made with the maximum possible number of identical trusses in size and pattern of the lattice. In turn, the implementation of the core lattice of the tower in the form of trusses, representing assembly units of factory readiness, simplifies the installation of the tower.

The core lattice of the tower is made of metal products with an angular profile, the supporting columns are made of metal products with a round tubular profile. The metal profile for the execution of the elements of the core lattice is acceptable from the point of view of perceiving multidirectional forces from the effects of the load.

The choice of a tubular profile for supporting columns is due to the fact that such a profile makes it possible to withstand static and dynamic multidirectional loads acting on the oil rig. From the course of resistance of materials it is known that an element with an annular cross section is equally strong, because its moment of resistance does not depend on the direction of the load.

A variant of the claimed tower is its equipment shelter, for example, soft. For this purpose, farms and other elements of the tower can be equipped with means for attaching the soft shelter of the tower, made in the form of metal loops intended for threading the cord of the soft shelter. Moreover, the use of farms provides the possibility of attaching soft shelter in the factory on horizontal truss belts, i.e. for a tower with a shelter, a prefabricated assembly unit in the form of a farm with an attached shelter panel is delivered to the installation site. Consequently, the use of farms provides an additional advantage in the possibility of mounting the tower with a ready-made shelter, which excludes installation work on fastening the shelter at a height, ensuring the convenience of mounting the tower regardless of the installation of the shelter. Elements of the lower sections of the tower and the integral module are also equipped with fastening elements for mounting soft shelter paintings.

These and other features of the inventive tower type towers are explained using the drawings and an example of the design of the tower with a useful height of 45 m used in a cluster drilling rig.

The figure 1 presents a view of the derrick from the receiving bridge of the drilling rig, figure 2 is a view of the derrick from the adjacent side; in figure 3 - trusses of adjacent rectangular sections, in figure 4 - a node for attaching a truss to a support column (node A), in figure 5 - a node for connecting adjacent belts of trusses of one rectangular section.

The tower derrick designed for use in a cluster drilling rig is made up of eight volumetric sections, which are the lower sections 1 — the “legs” of the derrick, the rectangular sections 2, the trapezoidal section 3, the additional trapezoidal section 4, the integral module 5 containing the upper section 6, and crown block 7.

The support columns are formed by the support elements 8, connected by height with the help of a finger joint. The faces of the tower are formed by a core lattice, the vertical faces of the tower contain a core lattice of the lower sections 1 and rectangular sections 2, and the inclined faces are the core lattice of the trapezoid section 3 and the additional trapezoid section 4.

The integral module 5 is formed by the upper section 6, made with vertical support elements 8, directly on which the frame 9 of the crown block 7 is installed with the necessary equipment: pulley sections, auxiliary pulleys (not shown in the drawing). The vertical supporting elements 8 of the upper section 6 are connected in height with the supporting elements 8 of the additional trapezoidal section 4 also by means of a finger connection.

The core lattice of the rectangular sections 2 and the trapezoidal section 3 are formed by trusses 10 with horizontal belts 11 and a rod triangular lattice 12. The trusses 10 are grouped within each of these sections, two on each side. Farms 10 of rectangular sections 2, forming vertical faces, are made identical in size and "pattern" of a triangular lattice. Moreover, in rectangular sections 2, identical trusses 10 can be installed with different orientations of the upper and lower horizontal belts 11 relative to each other. For example, in a rectangular section 2 with a balcony 13, the upper working truss 10 is installed so that the braces 12 of the core grid are not an obstacle for access for maintenance personnel to the technological equipment installed inside the tower (in the space limited by the faces of the tower). It should be noted that the balcony 13 is located inside the tower.

The trusses 10 of the rectangular sections 2 and the trapezoidal section 3 are connected with the supporting columns, namely: the horizontal belts 11 of the trusses 10 are attached to the supporting elements 8 of the sections 2, 3 by means of a detachable finger connection with the formation of the connection node shown in figure 4. So, axis 14, which is a connecting element, made with a shoulder 15, fixing the position of this axis 14, mounted in the eyes 16. The axis 14 is connected by means of a flexible connection 17 with the belt 11, which ensures its location in close proximity to the connection node tions, ensuring ease of installation.

In addition, within each such section 2, 3, the trusses 10 are connected in height, for this purpose the adjacent belts 11 of the trusses 10 are made with eyes 16, in which an axis 14 is installed, made with a shoulder 15, fixing the position of the axis 14. This connection node is shown in figure 5.

The lower sections 1 ("legs" of the tower) are made with horizontal belts 18, to which the braces 19 are attached using a detachable connection. Also, an additional trapezoidal section is made with horizontal belts 18 and braces 19.

For comfortable work of drilling rig personnel in areas with a temperate and cold climate, the tower in the mounting position contains a shelter, for example, in the form of panels of a “soft” shelter 20 attached to the elements of volume sections 1, 2, 3, 4 (except for the first lower section 1 ) To attach the panels 20 to the farms 10, the latter are equipped with means for attaching a “soft” shelter for the tower, made in the form of metal hooks 21, mounted on horizontal belts 11 and extreme racks of the core lattice 12 of the farms 10 and designed for threading the cord (not shown in the drawing) panels 20 soft shelter (see figure 3).

Factory-ready mounting units are delivered to the installation site of the tower-type tower: one-piece module 5 with crown block equipment 7, truss 10 with attached panels 20 of soft shelter, supporting elements 8, elements forming belts 18 and braces 19.

The installation of the claimed tower is carried out using a tower hoist (not shown in the drawing) installed on the sub-base of the tower hoist of the rig. The tower lift allows you to mount the tower in a "top to bottom" way, starting with an integral module, and ending with the lower section.

The horizontal support belts 11 of the trusses 10 are attached to adjacent supporting elements 8 of the respective sections by means of a finger joint, thus forming rectangular sections 2 and a trapezoidal section 3 of the tower.

The lower sections 1 of the tower are assembled by interconnecting the elements of the belts 18 and the braces 19 and attaching these braces 19 to the corresponding supporting elements 8. The elements of the lower sections are connected using a finger connection.

Installation of the tower begins with the installation of an integral module 5 with the upper section 6 on the elevator. Then, an additional trapezoidal section 4 is installed on the tower hoist, the ends of the supporting elements 8 of the upper 6 and the additional trapezoidal 4 sections are connected. In the same way, the trapezoid section 3, the rectangular sections 2, the lower sections 1 are connected in series.

To perform its function as part of the drilling rig, the installed tower-type tower is equipped with the necessary equipment (not shown in the drawing): stairs with transitional platforms installed in the space bounded by the faces of the tower, a balcony of the riding worker, including a store for placing drill pipes. In addition, the tower is equipped with a top drive system with guides.

The inventive utility model provides:

- simplification and ease of installation of the drilling rig through the use of unified units of factory readiness in the form of farms and an integral module that make up the main transport and installation modules of the drilling rig;

- increasing the stability of the tower by reducing the flexibility of the supporting columns, due to the fact that the attachment points of the trusses forming the core lattice of the tower faces (except for the lower and upper sections) to the corresponding supporting elements reduce the deflection of each supporting element;

- reduced installation time and ease of installation through the use of detachable finger connection of the elements of the tower.

Claims (10)

1. The tower derrick type, comprising a three-dimensional one-piece module containing a crown block, three-dimensional sections containing a rod grate forming the faces of the tower, and support elements connected in height to form support columns, while the three-dimensional sections consist of lower sections made in the form "Legs" of the tower, rectangular sections forming vertical faces, and a trapezoid section forming inclined faces; trusses of horizontal sections and a trapezoidal section are formed by trusses with horizontal belts, in each of the truss sections indicated two on each face are grouped and truss belts are attached to the corresponding supporting elements, and adjacent horizontal truss belts are interconnected; the volume one-piece module is formed by the upper section, including vertical supporting elements on which the crown block frame is mounted, and the supporting elements of the upper section are connected with the corresponding supporting elements of the trapezoid section. 2. The drilling rig according to claim 1, characterized in that it is provided with an additional section mounted between the trapezoidal section and the upper section. 3. The drilling rig according to claim 1, characterized in that the supporting elements are connected by means of a detachable connection, for example a finger connection. 4. The drilling rig according to claim 1, characterized in that in each rectangular and trapezoidal sections, horizontal truss belts are attached to the supporting elements by means of a detachable connection, for example, a finger connection. 5. The drilling rig according to claim 1, characterized in that the adjacent horizontal zones of the grouped trusses are connected in height by means of a detachable connection, for example a finger connection. 6. The drilling rig according to claim 1, characterized in that the elements of the core lattice of the lower sections are connected by means of a detachable connection, for example a finger connection. 7. A drilling rig according to claims 3 to 5 or 6, characterized in that the axis of the finger joint is connected to the elements of the core grid using a flexible connection, for example, in the form of a chain. 8. The drilling rig according to claim 1, characterized in that the core lattice of the derrick is made of metal products with an angular profile, and the supporting elements are made of metal products with a tubular round profile. 9. The drilling rig according to claim 1, characterized in that the volumetric sections are provided with a shelter made of soft panels. 10. The drilling rig according to claim 9, characterized in that the trusses are equipped with means for attaching soft shelter panels made in the form of metal loops designed to thread the cord of soft shelter panels, while metal loops are fixed on the horizontal truss belts and the extreme racks of the core grid farms.