BG113261A - Rotary arm system - Google Patents

Abstract

The invention relates to a system with a rotary arm, which will find application in the field of devices and methods for construction, maintenance and demolition of buildings or other structures shaped like a sphere, part of a sphere or other similar shape. The system comprises a track (1) (rail or other base) mounted around a building structure (2) and a movable platform (3) mounted on the track (1). One end of a spatial vertical rotary arm (4) is fixedly attached to the movable platform (3), the other end of which is mounted to the top of a fixed vertical mast (6) by means of a hinged connection (5). The vertical mast (6) is mounted to the base of the building structure (2). A support carriage (9) is mounted to the spatial vertical rotary arm (4), which can be moved along it.

Description

SYSTEM

WITH POTATOPHO SHOULDER

Field of technology

The present invention relates to a rotary arm system which falls and will find application in the field of devices and methods for construction and maintenance, as well as in the demolition of building or other structures in the form of a sphere, part of a sphere or other spatial form .

BACKGROUND OF THE INVENTION

Those involved in the construction, maintenance and demolition of various building structures are constantly looking for ways to perform these operations more efficiently and in less time. Especially in building structures with unusual shapes such as domed structures, the implementation of certain tasks can be challenging due to the difficulties associated with the safe positioning of equipment and workers near the work site, which would also allow the operator to work faster. .

When construction equipment is located relatively close to the work site, it is more stable and can move heavier loads with higher mobility. Working with heavy equipment, which for various reasons must be located and stabilized at a greater distance from the working structure, can be essentially less safe and risky, and less effective.

In the case of construction machinery located at a distance from the structure under construction, additional stabilizers and equipment may be required. The loading and lifting limits must be strictly observed and the device must be located as close as possible to the load to be lifted. Especially in tight spaces, such as urban environments, enclosed spaces and the like, the lifting area and its perimeter must be carefully and strictly observed.

No such design of a rotary arm system is known.

Technical essence of the invention

The object of the invention model is to create a system with a rotary arm, which will facilitate the process of construction, maintenance and maintenance of various volumetric building or other structures, especially with dome-shaped or part-sphere shapes.

This problem is solved by a system with a rotary arm, which consists of a movable platform mounted on a track, to which one end of a spatial vertical rotary arm is connected, the other end of which is hinged directly to the serviced structure or to the top of a fixed vertical mast. The vertical mast is attached to the base of the structure. A support sled with the possibility of moving on it is mounted to the spatial vertical rotary arm.

According to one variant, at the two ends of the fixed vertical mast - the base and the top are mounted lower and upper plate.

The track, the movable platform, the spatial vertical rotary arm and the supporting slide are located inside or outside the three-dimensional structure on which the structure performs at least one of the construction, service and maintenance activities.

According to one variant, the path is established above the base of the three-dimensional structure, on which at least one of the construction, service and maintenance activities is performed.

According to another variant embodiment of the invention, the mobile platform is provided with wheels by means of which it moves on rails attached to the track.

The three-dimensional vertical rotary arm is mounted to the fixed vertical mast or directly to the structure and can be rotated around it.

The spatial vertical rotary arm is multicomponent, with variable length and shape and with the possibility of bending.

At the same time, the spatial vertical rotary arm may be concave or convex.

According to one variant embodiment, the carrier slide is provided with devices for performing operations on the structure.

with

The support slide may be provided with a device attached to it for gripping and lifting the telescopic arms used for the construction.

According to a further embodiment, the rotary arm system is programmed and robotic and can operate without human intervention.

The advantages of the invention are the ability to automate and robotize construction work in the construction of hemispherical structures.

Another major advantage is the ability to dispose of the entire volume of warehouses with a hemispherical shape.

This device will be used both for the construction of such domed structures and their maintenance - inside and outside, such as performing creeping formwork, coating, painting and other operations, and for servicing storage areas with a hemispherical structure.

Explanation of the attached figures

An exemplary embodiment of the invention is shown in the attached figures, where:

FIG. 1 is an axonometric view of a rotary arm system mounted to and around a domed (hemispherical) structure,

FIG. 2 - top view of the rotary arm system mounted to and around the dome (hemispherical) structure,

FIG. 3 - top view of the rotary arm system mounted to and around the dome (hemispherical) structure and of the

FIG. 4 is a close - up axonometric view of the movable platform of the system with a rotary arm mounted on a track.

Exemplary implementation of the utility model

An exemplary embodiment of the rotary arm system, which is suitable for use mainly in spherical or hemispherical domed structures, is shown in the attached figures 1, 2, 3 and 4, which show the components and connections between the components of the system.

The system consists of a track 1 (rail or other road base) established around a hemispherical building structure 2 and a movable platform 3, which is mounted on the track 1. To the movable platform 3 is fixed one end of a spatial vertical rotary arm (truss) 4, the other end of which is mounted by means of a hinged connection 5 to the top of a fixed vertical mast 6 - fig. 1.

The vertical mast 6 is established in this case by means of a lower plate 7 to the base of the hemispherical building structure 2. In the upper part of the vertical mast b, to the top of the building structure 2, an upper plate 8 is mounted.

The shape of the spatial vertical arm 4 follows the shape of the outer surface of the building structure 2.

In one embodiment, not shown in the attached figures, the upper end of the spatial vertical arm 4 can be fastened by means of a hinge connection 5 and to the top of the building structure 2 or to the upper plate 8.

A support sled 9 is mounted to the spatial vertical rotary arm 4, which can be moved up and down along it - fig. 2.

In addition, the attached figures show the additional components included in the system, which have been or are used to build and provide the frame for the dome or other building structure 2. These additional components include spatially vertical elements 10, spatially horizontal elements 11 and telescopic arms 12. These optional components, as well as the mechanization function allowing the telescopic arms 12 to be moved by means of ropes 13, are provided and described in detail in the publication in application WO2018 / 014094A1, which should be considered fully incorporated herein by reference.

The vertical elements 10 can be steel bars that bend and bend in the process of building the frame of the building structure 2. The horizontal elements 11 are also steel bars that bend and bend in circular and / or spiral shapes and are placed around the vertical elements 10. The horizontal elements 11 are mounted on different levels of the dome structure 2 and have a smaller radius and circumference from bottom to top, as the technological process moves from bottom to top along the dome structure 2.

The horizontal elements 11 can be attached to the vertical elements 10 by welding or detachable with clamps or in another known manner.

The telescopic arms 12 can be used to bend the vertical elements 10 into a curved shape. The telescopic arms 12 attached to the base of the vertical mast 6 and in this case to the lower plate 7 are directed from the inside to the outside and can be made of different lengths depending on the shape of the building structure 2. The outer edges of the telescopic arms 12 they can move up and down, engage the vertical elements 10 so as to bend them towards the mast 6, until the ends of the telescopic arms 12 move upwards. The vertical elements 10 are clamped at the top of the structure 2 by means of the last horizontal element 11 or are fixed in radial holes, which are made in the upper plate 8.

The movement of the telescopic arms 12 on the vertical elements 10 is done in two ways - the first is with the help of ropes 13, which are stretched or with the help of a device for lifting them, mounted on the supporting sled 9.

When the rotary arm system is used to service an already constructed three-dimensional structure, the hinge connection 5 can be located on the pole of the hemisphere or structure 2, both for external and suspended bracket for internal installation.

The mechanization to the base of the vertical mast 6 drives the raising and lowering of the outer ends of the telescopic arms 12. The telescopic arms 12 also grip and raise the horizontal arms 11 to their respective level vertically along the domed structure.

In some embodiments, one or more of the outer ends of the telescopic arms 12 may be attached to the support carriage 9 to allow them to be raised or lowered.

Examination of the attached figures shows that the spatial vertical rotary arm 4 is concave and bends or curves upwards and above the outer surface of the dome structure 2. In various embodiments, the spatial vertical rotary arm 4 may be flexible to allow curvature change. Although the figures show the spatial vertical rotary arm 4 mainly as a single or double steel element, in alternative embodiments the arm 4 may not be made of steel but may be made of another material such as aluminum or composite material. The rotary arm 4 can also be made of many component elements connected to each other.

With the rotary arm system, not only can materials and tools be lifted and moved, but it can also be used directly to build domed structures. Since the tools placed in the carrier carriage 9 can be robotic, remotely programmed and controlled, they can perform various tasks on the structure 2 during construction, maintenance, demolition and / or other operations.

The system can also be used in three-dimensional printing applications for construction or other operations on a structure.

Once the frame has been placed on the domed or otherwise shaped structure 2, for example by using the additional components described above, it is possible to proceed to placing the shapes or panels to the structure 2 and fixing these shapes or panels in place. on the frame by welding or otherwise. Insulating components can also be attached. The rotary arm 4 can move in a radius of 360 degrees around the structure, and the bearing carriage 9 can be moved up or down along the spatially vertical rotary arm 4.

As noted, the actions provided herein make it possible to reach any point on the surface of the dome structure 2 and to carry out the operations using the various tools established in the sled carrier 9.

The movable platform 3 of the rotary arm system, when mounted on a rail track 1, is provided with wheels 14 for moving on the rail track 1.

When the system is involved in the construction of the metal structure 2, it can be used to supply vertical reinforcing bars or reinforcing elements listed above as vertical and horizontal elements 10 and 11. When the structure 2 is fully constructed, the system can remain outside and to be used for finishing works such as painting. When the construction is complete, the system can be dismantled.

One of the variants of the device does not require the placement of track 1 (rail) on the ground or at the base of the building structure 2, regardless of whether this structure is completed or not. Instead, track 1 (track) can be mounted on raised platforms, using for example jacks or other higher-level devices, and does not interfere with the construction of the doors and windows that form the basis of the structure 2.

The variants also do not require the path 1 to completely surround the structure 2, because in this way the blocking of the doors and windows is avoided or other installation operations are prevented.

The variants also do not require path 1 to be round. It may have another arbitrary shape according to the shape of the building structure 2.

The rotary arm system can be used not only for construction and maintenance inside and outside of various volumetric structures, but if necessary it can also be used for their destruction and destruction.

Claims (10)

PATENT CLAIMS Rotary arm system, characterized in that it consists of a movable platform (3) mounted on a track (1), to which one end of a spatial vertical rotary arm (4) is connected, the other end of which is mounted by means of hinged connection (5) directly to the serviced structure (2) or to the top of a fixed vertical mast (6), installed to the base of the structure (2), and a bearing slide (9) is mounted to the spatial vertical rotary arm (4) to move on it. Rotary arm system according to claim 1, characterized in that a lower (7) and an upper plate (8) are mounted at both ends of the fixed vertical mast (6). Rotary arm system according to claims 1 and 2, characterized in that the track (1), the movable platform (3), the spatial vertical rotary arm (4) and the support slide (9) are located inside or outside the structure 2) on which at least one of the construction, service and maintenance activities is performed. Rotary arm system according to claim 1, characterized in that the aisle (1) is established above the base of the structure (2) on which at least one of the construction, service and maintenance activities is performed. Rotary arm system according to claim 1, characterized in that wheels (14) are mounted on the movable platform (3), by means of which it moves on rails mounted to the track (1). Rotary arm system according to claim 1, characterized in that the spatial vertical rotary arm (4) is mounted to the fixed vertical mast (6) or to the structure (2) and can be rotated around it. Rotary arm system according to claims 1 and 6, characterized in that the spatial vertical rotary arm (4) is multicomponent, of variable length and shape and with the possibility of bending. Rotary arm system according to claims 1, 6 and 7, characterized in that the spatial vertical rotary arm (4) has a concave or convex shape following the shape of the structure. Rotary arm system according to Claim 1, characterized in that the support carriage (9) is provided with devices for performing operations on the structure (2) attached to it. Rotary arm system according to claims 1 and 8, characterized in that the support carriage (9) is provided with a device for gripping and lifting the telescopic arms (12) used to build the structure (2). . Rotary arm system according to claim 1, characterized in that the system is programmed and robotic and can operate without human intervention.