PL168643B1 - Single- or multiple-deck suspended working platform and method of preparing such platform for work in avertical shaft - Google Patents

Abstract

single or multi-level deck hanging, suspended on a sling, containing at least one landing made of load-bearing girders and the platforms are connected between poles with each other, characterized in that skeleton / frame / platform, preferably structured box, fully welded includes conveniently three bearing girders (3) formed at an angle with equal arms, facing inwards, being these arms are connected with a stiffening beam (4) penetrating through the supporting poles (1) and the ends adjacent girders (3) box-like structure preferably located they are provided in parallel from the top in oblong cutouts for articulated mounting tilting elements on pins (12) installed in the arms bearing beams (3).

Description

The subject of the invention is a single or multi-level suspension platform and a method of preparing, in particular, a multi-level suspension platform for servicing a vertical shaft. The technical solutions according to the invention are intended for the construction of a suspension platform and for the preparation of this platform for the shaft service, in particular the assembly, disassembly or replacement of high-voltage cables, ducts, pipelines and other elements of the shaft reinforcement, and for emergency and intervention works in the shaft, requiring quick action. especially where working from a bucket is dangerous or even impossible, especially in a shaft with a large diameter. The hanging platform is used when revising the shaft along its entire depth and at every point of its space due to the fact that it allows access to each element of the reinforcement and shaft lining. The hanging platform can also be used to evacuate the crew from the shaft in the event of an emergency with risk elimination due to the possibility of reaching virtually any point in the shaft space, i.e. where the crew may be located, such as a pump chamber or an inlet of a mining excavation.

Known full suspension bridge from the book: Kostrz Jan: Górnictwo T. VI. Execution of excavations, part I. Hollowing of shafts using the standard method from the surface. WG-H Katowice 1961 pp. 172-175 and Figs. 81 and 84 consists of two platforms connected with each other by columns. The platforms' supporting girders are simple cross sections situated in relation to each other, connected at the periphery by a wheel-shaped supporting girder composed of a series of arched elements. The arrangement of the load-bearing beams is such that it is possible to pass buckets, pumps, central riser, pipelines and ducts. The decking of the platforms is made of corrugated sheets or 50 mm thick logs.

To suspend the platform, a sling is used, consisting of a gusset head (plate), consisting of two triangular plates connected with each other with bolts. The nodal head is connected from the top to the end of the supporting rope by a bolt, and in the lower part symmetrically at the corners with the ends of the auxiliary carrying rope, and in the axis of the head, on the mandrel, there are two handles for the ends of the auxiliary ropes. At the bottom, the auxiliary ropes are connected to the turnbuckles with a grip, which in turn are connected with the load-bearing beams of the suspension platform by means of tension rods.

The installation of the known suspension platform is possible only in the shaft, which is burdensome and dangerous in practice. The hanging platform blocks the shaft, which makes it impossible to perform other works related to the operation. During use, the platform requires the use of bolts embedded in the previously prepared sockets of the shaft housing, which causes local weakening of the housing and the need to prepare these sockets, which in the case of concrete housing causes its permanent damage. The production of platform arch girders is cumbersome, while all the platform load-bearing girders have a considerable weight and during assembly, making connections, especially of platform elements, is difficult due to the difficult working conditions prevailing in the mine shaft. The known suspension of the suspension platform does not allow hanging on a hook and moving horizontally in the mine shaft from one rope to the other lifting rope with the load suspended. Although it contains four auxiliary ropes, this sling does not eliminate the tilt of the suspension platform, and the adjustment

168 643 the platform tilt is cumbersome by the turnbuckle, the strength of which is also lower than that of the auxiliary rope.

A known method of preparing the suspension platform for intervention works in the shaft is based on the fact that individual assemblies (elements) of the platform are made in a workshop. The elements should be dimensioned in such a way that they can fit into the passage of the timber deck. The trial assembly of the entire platform and the marking of the cooperating components are carried out in the workshop. Then, the hanging platform is transported to the shaft frame. In turn, the existing shaft reinforcement is adapted, if it exists for the operating platform, or the construction and installation in the shaft of the operating platform is carried out, enabling the assembly and disassembly of the platform hanging in the shaft. The platform hanging from the shaft structure in the form of its components is lowered into the shaft onto the operating platform on which the shaft deck is mounted. After the intervention works in the shaft are completed, the hanging platform on the operating platform is disassembled and its individual elements are pulled to the shaft framework. Finally, the operating platform in the shaft is disassembled.

An inconvenience of the known method of preparing the suspension platform for the performance of intervention works in the shaft is the necessity to install the operating platform in the shaft and to conduct the assembly and disassembly of the suspension platform in the shaft on this platform, brought in parts to the operating platform from the shaft structure.

The known vertical mine transport vessel in shafts from Polish patent specification No. 118 681 has a cylindrical body divided by at least two horizontal landing plates covering the vessel's cross-section. The plates are permanently connected to the supporting closed rings, which, through knots, connect with the horizontal strands of the vessel suspension. The upper and middle landing plates have closed manholes for communication between the platforms. The sides of the vessel are made of an openwork basket with gates sliding in a circle, situated between the platform plates. Through the gate in the side of the vessel, materials are placed or the crew can climb onto each landing plate, except for the highest one. Access to the topmost slab is via a ladder through the manhole. The upper deck plate is 1.2 meters below the edge of the upper sidewall, and above the upper deck plate, the basket is open from above.

The vessel's supporting system consists of two tension members located opposite on the vessel's side, parallel to its longitudinal axis, connected with each other by three closed rings supporting the landing plates, situated in planes perpendicular to the longitudinal axis of the vessel. In the upper part of the pull-up vessel, the load-bearing beam is connected with the hanger located in the longitudinal axis of the vessel, suspended on the hook sling of the temporary hoisting device through two articulated joints with the axes perpendicular to each other in the vertical projection, and two joint joints with axes parallel to each other. shunt.

The known vertical transport vessel reduces the number of cycles of movement of the extraction vessel for the crew's exit and departure and increases the functionality of its use by simultaneously enabling people to travel and transporting materials, as well as performing revision and repair works in the shaft.

The disadvantage of the vertical mine transport vessel in the shaft is its small range for revision and repair works in the shaft, and in practice it prevents safe access to any place in the shaft space. Despite concentrating the mass of the vessel around the vertical axis, the vessel is unstable, especially the bottom of the vessel, which may deviate significantly from the vertical axis.

Known from the description of the utility model No. Ru-40318 is a shaft deck intended for the control of balance ropes, especially multi-ropes in the shaft. The platform is of welded construction and consists of a rectangular frame much longer than its width, made of trough profiles facing each other. Its length corresponds to the clearance of the glazing reinforcement, and its width, while keeping the minimum size, is adjusted to the distance between the guides. The frame was reinforced with a few crossbars and covered with a perforated plate. It is supported on supporting girders by hinges built-in at its beginning and a flexible seat built-in at its end. Above the seat to

In the frame, there is a catch connected by a rope through a pulley to a manual reel. Both the pulley and the reel are attached to the shaft lining. Tilting barriers are installed on both sides of the frame along the entire route. They are composed of longitudinally hinged poles, which are also hinged to the frame. Their vertical position is secured at the beginning on the first post with a bar connecting them non-displaceably with the frame and on the last transverse post with a hook connecting both rails with each other.

Two such platforms are used to carry out the compensatory checks of the ropes, the lower one is a working platform, and the upper one without barriers, attached to the shaft reinforcement, is a cover for employees working on the lower platform. After the inspections, both platforms are lifted with reels and fixed in a vertical position on the shaft lining.

The production of the known shaft deck is not complicated, and its use is easy and convenient for people who check the balance ropes from it. An additional advantage of the shaft platform is placing the platform within easy reach of the controlled ropes.

The known shaft deck is intended for single-purpose shaft operation, and its main disadvantage is that it is installed stationary at a certain height in the shaft. It cannot be treated as an exhaust vessel at the same time.

The object of the invention is to remove or at least reduce the inconvenience of the known suspension platform or mine vertical transport vessel and the method of preparing the suspension platform for servicing a vertical shaft. In order to achieve this goal, the task of developing an improved structure of a single- or multi-level suspension platform and a method of preparation, especially a multi-level suspension platform for servicing a vertical shaft, allowing for the minimized volume of the suspension platform structure, displacement of this platform through the opening on the core of the small shaft and preparation for service with a range ensuring access to each point of the shaft space vertically and horizontally.

This task is solved in accordance with the invention in that the platform framework (frame), preferably with a fully welded box-type structure, advantageously comprises three bearing girders formed at an angle with equal arms directed inwards, the arms being connected by a stiffening beam penetrating through the supporting columns , and the ends of adjacent box-type support beams, preferably arranged in parallel, are provided at the top with longitudinal cutouts for articulating the pivoting elements on pins installed in the arms of the support beams. The platform frame, suitably in the shape of a regular hexagon circumscribed on a circle, has tilting elements alternately installed on one side, and on the other side, the platform frame is connected at least to the overhead guard and / or to a further frame vertically by means of support columns. Above the platform, above which the protective canopy is built, in the supporting posts, bolts for cockles for the tendons of multi-legged suspensions are installed, in which the bearing element of the head is a pin, on which a sleeve is mounted in the upper part, detachably connected with the bent splints in the middle, and the lower part of the splints it rests on a rotating ring mounted above the rolling bearing, resting on the abutment ring, while the pin from the top, through a transverse hole, is connected by a pin to two plates with a shape similar to an isosceles triangle, and at the top two corners of the plate are provided with bows connected by a pin. The tilting element consists of side (longitudinal) sections connected with each other by crossbars, which are covered with a covering, and protective barriers are built on the sides. The tilting elements may also have transverse beams connected by separate supporting lines to the trunk of the shaft. The tilting elements have rope guides and rolling guide rollers. The tilting element constituting the tilt footbridge has side (longitudinal) sections connected with counterweights penetrating through the ends of the arms of the platform frame bearing girders, which are equipped with weights.

The determined task is also solved by the preparation method, especially of the multi-level suspension platform for servicing the vertical shaft, characterized by the fact that the assembled suspension platform with tilting elements raised to the vertical position

168 643 the rope sling is conveniently suspended on the hook of the bucket sling and is lowered to a certain depth in the shaft, where the previously lowered end of the lifting platform lifting rope, after which the hook of this sling is placed on the multi-leg sling of the suspension platform, and the bucket rope is loosened until the rope is stretched suspension platform, then the suspension platform moves horizontally from the bucket passage to the work site, then the hook of the bucket sling is unfastened and the hoisting rope is released, while after hanging the platform hanging on its lifting rope in the shaft, tilting elements and railings are opened, first on the lower landing and the tilting elements are installed, and the tilting elements of considerable length are connected with the rope lashings attached to the supporting poles, then the tilting elements are opened at higher levels, and after unfolding each of the tilting elements at individual levels, they are secured with bolts. The suspended platform with the multi-leg sling connected to the rope of the suspended platform is lowered in the shaft directly to a certain height and begins to unload the tilting elements. In order to balance the suspension platform statically, weights are placed on the foot pillar on the lower platform.

A single or multi-level suspension platform and the method of preparation, in particular a multi-level suspension platform for servicing a vertical shaft according to the invention, enable the complete platform to be lowered quickly into the shaft using a bucket sling or its own lifting rope, and this platform to be pulled out equally quickly to the shaft framework. The solution according to the invention eliminates the need to install the suspended platform in the shaft, and thus the employment of workers in the assembly of the suspended platform in the shaft. Thanks to this, the hazardous work related to the disassembly of the hanging platform in the shaft as well as the assembly and disassembly of the operating platform in the shaft is also eliminated. The stability of the suspended platform is increased by the use of multi-leg slings and bow guides for guide ropes. The sheet metal inserts inserted into the load-bearing pillar enable precise static balancing of the suspended platform. The structure of the suspension platform according to the invention is considerably lighter than the structure of the known suspension platform. The suspension platform, also due to the way it is prepared for the operation of the shaft, can be used many times for work in various shafts with diameters, in particular from 6.5 to 9.5 m, with little modification of the tilting elements. Several tilting elements can be made in advance for different shaft diameters. Thus, the solutions according to the invention can be used for emergency works in the shaft. The hanging platform can also be used as an emergency-auxiliary lift vessel (stationary or transportable). The suspension platform according to the invention is also characterized by its versatility, as it can be used in various types of shafts, regardless of the shaft diameter and shape, and regardless of the shaft depth or the function that the shaft performs (inhalation, exhaust, material-descent). The suspension platform according to the invention makes it possible to quickly reach any point in the shaft, which is of paramount importance for rescue and emergency lifts.

The subject of the invention is illustrated in the drawing in which fig. 1 schematically shows a two-deck suspension platform with folded-out tilting elements of different lengths together with a multi-leg sling in side view, fig. 2 a two-deck suspension deck with folded-out tilting elements in a horizontal section along the length the line A - A marked in Fig. 1 in top view, Fig. 3 - two-deck suspension platform after lifting the tilting elements into the vertical position in a horizontal section along the line A-A marked in Fig. 1, Fig. 4 - two-deck suspension platform with in a horizontal section along the line A-A marked in Fig. 1 and in top view, Fig. 5, two-deck suspended platform after lifting the tilting elements with additional lifting ropes in a horizontal section along the line A - unfolded tilting elements with additional lifting ropes A shown in Fig. 1i in a top view, Fig. 6 - a two-deck platform hanging in a shaft with unfolded elements with tilting elements of various lengths together with the multi-leg sling and the hoist of the hoisting device in a side view, Fig. 7 - a two-landing platform hanging in the shaft with folded-out tilting elements of various lengths and the hoisting device vessel in a horizontal section along the line B - B marked in Fig. 6 and in top view, Fig. 8 - frame of the lower landing of the suspended platform in top view, Fig. 9 - frame of the upper landing of the suspended platform in top view, Fig. 10 - communication footbridge with

168 643 counterweight in a side view with a platform frame element in a vertical section, Fig. 11 - communication footbridge with counterweight with a landing element in a top view.

The two-landing suspension platform consists of two working levels in the form of platforms and a protective canopy connected with each other with load-bearing poles 1, and a ladder 2 from the inside.

The main part of each of the platforms is a frame with a welded structure and the shape of a regular hexagon described on a circle with a diameter of 1.9 m, and therefore equal to the diameter of the bucket with a capacity of V = 4.0

The frame (skeleton) of the upper and lower platform consists of three bearing girders 3 formed at an angle with equal arms, directed to the vertical axis of the hanging platform. These arms are inseparably connected by a channel 4, which passes through the supporting column 1, while the supporting column 1 is in turn connected by a section 5 to the supporting beams 3. The supporting girders 3 are connected with each other by transverse sections 6 fastened crosswise in the center by a section 7 The internal transverse profiles 6 in the lower landing (Fig. 8) are connected with perpendicularly situated supports (connectors) 8 connected in the axis of the landing frame. In the upper landing (Fig. 9), two internal transverse sections 6 are connected to each other by a beam 9, and on the extension to the center of two arms of the supporting girders 3, supports 10 are installed for the hatch, with a ladder 2 with bows on one side of the hatch. . Ladder 2 is installed from the lower landing through the upper (middle) landing to the protective canopy.

Above the upper landing, on the extension of the load-bearing columns, 1 built-in protective canopy, a structure similar to the platform's frame. The protective roof is equipped with a hatch closed with a hatch, in which a ladder 2 is located, and a guard rail around the hatch.

The supporting girders 3 have a box structure and are provided at the ends of the arms with longitudinal cuts for pivoting mounting of the tilting elements on the pins 11 and 12, while the bolts 11 at the very end of the arms of the supporting girders 3 are intended to protect, on both sides, of the tilting element against accidental lifting. On the load-bearing beams 3 above the bolts 12 connecting the tilt elements, on both sides of the lug (yoke) 13 are installed to keep the tilt element in the vertical (folded) position. Tilting elements longer than 2 m are connected with ropes 14 attached to the supporting poles 1. Above the upper landing in the supporting poles 1 there are holes for bolts for cockles 15 for the strands of the three-leg sling. The ropes of the slings pass through the holes lined with rubber in the protective canopy.

The three-leg sling consists of a head mounted on a bearing pin 16 flattened from above and provided with a transverse hole. A sleeve is mounted in its upper part on the bearing pin 16, detachably connected to three bent flaps 17 in the center by an angle of 120 °, with a shape similar to a triangle. The sleeve on the cylindrical side surface has vertical holes cut for the upper part of the splines 17. The bent splints 17 in the corners have openings for transverse pins on which the cockles are mounted for connection with the rope ties. In the lower part of the support pin 16, a thrust roller bearing is mounted, resting on the thrust ring, while above the roller bearing on the support pin 16, a rotating mushroom ring is mounted on the support pin 16 inseparably connected to the central part of the bent splines 17, the individual splines 17 they have a cut-out at the point of connection with the ring and thus rest on the ring.

The bearing pin 16 of the sling head is connected from the top on both sides by a pin to two plates 18 in the shape similar to an isosceles triangle, with the upper corners of the plate 18 being rounded, and in them there are openings forming bows connected with each other by transverse bolts, while in of the entire plate 18 with pins form a lever. The bow located along the diagonal has a pin for a hook 19 connected by a link with an installed cockle 20 to the carrier rope, and a taper link can be installed on the pin in the shackle diagonally with respect to the carrier pin 16 for connection to the hook of the carrier rope.

The load-bearing columns 1 in the section between the platforms contain two bolt connections, not shown in the drawing, enabling the adjustment of the distance between the platforms in the range of 2 - 9 meters.

168 643

The tilting element consists of longitudinal I-beams 21 connected with crossbars, which are covered with a covering, and on the sides, on both sides, protective rails 22 are built-in. The safety rails 22 are also installed on the platform frame in the openings of the C-section 4, constituting a stiffening beam for the load-bearing girder 3. Railings the protective covers 22 are therefore installed around the perimeter of the entire lower and upper (middle) landing and also on the overhead protection canopy.

The two-deck suspension deck shown in Figs. 4 and 5 has tilting decks connected by separate lifting ropes to the trunk of the shaft. In tilting platforms, the transverse beams 23 contain splines with holes for bolts for the hearts of the lifting ropes. The main lifting rope is mounted on the winch, and the additional three lifting lines of the tilting platforms (elements) are fixed in the steel structure with self-locking cockles.

The two-deck suspension platform shown in Figs. 6 and 7 has two tilt elements adapted to the shaft casing and these tilt elements have rope guides 24 and guide rollers 25, and the third tilt element (tilt footbridge) directed towards the center of the shaft is formed in the form of a polygon, enabling getting out or boarding into both extraction vessels. The tilting footbridge in the form of a polygon is lifted upwards when working with the other two tilting elements in order to allow the normal movement of the extraction vessels. Thus, the tilting bridge is lowered and lifted several times in turns for the crew working on the suspension platform.

The tilting bridge shown in Figs. 10 and 11 has longitudinal I-sections (beams) 21 connected to counterweights 26 penetrating through the ends of the arms of the supporting girders 3 of the platform frame, reaching under the landing. The shelves of the counterweight 26 are closed with welded flat bars, and inside, on both sides of the counterweight 26, weights 27 are placed. The weights 27 are secured against falling out by means of detachable connections that allow for the adjustment of the position of the mass of the mass of the mass 27 in relation to the axis of rotation, which is the pin 12. Counterweight 26 and weights 27 make it easier to raise and lower the tilting bridge working as a communication bridge.

The method of preparing the two-level suspension platform for servicing the vertical shaft consists in making the elements of the platform and its assembly in the workshop. The assembled suspension platform is transported to the shaft frame. Then, the suspended platform with the tilting elements of the three-leg sling raised to the vertical position is suspended above the shaft's log on the hook of the bucket sling and is lowered to a certain depth, where the end of the suspension platform lifting rope has been lowered earlier. Next, the hook of this sling is attached to the three-leg sling, then the bucket rope is slowly slackened until the lifting rope of the suspension platform is stretched. Then the platform moves horizontally from the bucket passage to its working place, and the hook of the bucket sling is released and the hoist rope is released. After the platform hanging on its bearing rope is suspended in the shaft, the tilting elements and barriers 22 are folded out on the lower landing and the rope bow guides 24 are mounted on the platform stabilizing ropes. These are mainly steel decking ropes. Tilting elements with a length of more than 2 m are connected with the ropes 14 attached to the supporting poles 1. Then, from the lower landing, the ladder 2 goes to the upper landing, and the tilting elements are disassembled, protective rails 22 are installed, and bow guides 24 are installed. After unfolding each of the tilting elements on both platforms, they are secured with bolts 11. Pins 11 prevent accidental lifting of the tilting element. The bolts 11 are attached to the platform with chains so that they do not accidentally fall into the shaft. In turn, the condition of mounting of all protective barriers on the platform platforms is checked and the installation of the guide rollers 25 to the tilting elements is started. After these operations, the suspension platform is ready to perform the planned works and is also ready to be moved in the shaft on its carrying rope. If necessary, it is possible to balance the platform statically with the help of weights inserted into the load-bearing column 1 above the lower platform. The shortest tilting element on the platform acts as a communication footbridge for the passage from the suspended platform to one of the lifting vessels or vice versa. This element usually belongs to the upper landing and has a counterweight 26

168 643 to facilitate its swinging away. On the other hand, lowering or lifting the other tilting elements will be necessary only when unfolding the platform, after lowering it into the shaft and during folding the platform before pulling it onto the shaft framework. To facilitate this operation, a manual hoist is attached to the load-bearing pillar 1 of the platform at the appropriate height.

After servicing the shaft, the tilting elements on the upper landing are lifted to the vertical position, and then on the lower landing, and then the hanging platform is pulled out to the shaft's frame. The activities related to extending the deck onto the shaft framework are analogous, but they are performed in the reverse order. First, the hook of the bucket sling is fastened to the sling of the three-leg suspension platform. The rope of the bucket sling will then be pulled slowly until it takes over the entire load of the platform. The platform then moves horizontally to the bucket passage. In turn, the sling hook of the platform carrying rope is released and the platform is ready to be pulled out to the shaft frame. The above activities of connecting the platform and the carrying rope to the rope of the bucket sling and vice versa are performed from the protective canopy.

Improvements and additions are planned in the design solutions of the suspension platform. For example, the tilting elements are connected with each other with horizontal platforms, which increases the working space of the platform. Horizontal platforms between the tilting elements can cover the entire space of the horizontal section of the shaft.

Fig. 3

168 643

Fg. 5

168 643

Fig. 6a;

168 643

Fig.7

168 643

3 4 5 6 7 8

Fig.8

168 643

7

Fig. 9

168 643

Fig.10

Fig.11

168 643

Fig.1

© 2 , \

Publishing Department of the UP RP. Circulation of 90 copies. Price PLN 1.50

Claims (10)

Patent claims 1. A single or multi-level suspension platform, suspended from a sling, comprising at least one landing made of load-bearing beams and the platforms connected by columns, characterized in that the skeleton / frame / platform, preferably box-shaped, fully welded, comprises suitably three supporting girders (3) formed at an angle with equal arms directed inwards, the arms being connected by a stiffening beam (4) penetrating through the supporting poles (1), and the ends of the adjacent supporting girders (3) with a box structure preferably arranged in parallel they are provided with longitudinal cutouts on the top for articulated mounting of tilting elements on pins (12) installed in the arms of the supporting girders (3). 2. A single or multi-level suspension platform according to claim 3. The platform frame according to claim 1, characterized in that the platform frame, suitably in the shape of a regular hexagon circumscribed in a circle, has tilt elements installed alternately on one side, and the platform frame is connected on the other side at least with a protective canopy and / or a further frame vertically by means of load-bearing columns (1). 3. A single or multi-level suspension platform according to claim 1. The method of claim 1, characterized in that above the platform above which the protective canopy is built, in the supporting poles (1), bolts for cockles (15) for strands of multi-legged suspensions are installed, in which the head bearing element is a pin (16), on which there is a sleeve detachably connected to the flaps (17) bent in the middle, and the lower part of the flaps (17) is supported on a rotating ring mounted above the rolling bearing, resting on the abutment ring, while the mandrel from the top through the transverse hole is connected to two plates (18) with a shape similar to an isosceles triangle, and at the two upper corners of the plate (18) with arches connected with bolts. 4. A single or multi-level suspension platform according to claim A method according to claim 1 or 2, characterized in that the tilting element consists of side (longitudinal) sections (21) connected with crossbars, covered with a covering, and protective barriers (22) on the sides. 5. A single or multi-level suspension platform according to claim A method as claimed in claim 1 or 2, characterized in that the tilting elements have transverse beams (23) connected by separate supporting lines to the trunk of the shaft. 6. A single or multi-level suspension platform according to claim A device as claimed in claim 1, characterized in that the tilting elements have line guides (24) and rolling guide rollers (25). 7. Single or multi-level suspension platform according to claim A device according to claim 1 or 2, characterized in that the tilting element, which is a tilting bridge, has side (longitudinal) profiles (21) connected with counterweights (26) penetrating through the ends of the arms (3) of the platform frame, which are provided with weights (27). The method of preparing, especially the multi-level suspension platform for servicing the vertical shaft, consisting in the production of individual components and assembly of the entire platform in the workshop and lowering the platform to the shaft, characterized in that the assembled suspension platform with tilting elements raised to the vertical position is hung conveniently on the side of the bucket sling and is lowered to a certain depth in the shaft, where the end of the lifting platform's lifting rope has been lowered, then the hook of this sling is placed on the multi-leg sling of the suspension platform, and the bucket rope is loosened until the lifting platform's lifting rope is stretched, then The suspension platform moves horizontally from the bucket passage to the work site, after which the hook of the bucket sling is unfastened and the hoisting rope is released, in turn after hanging in the shaft 168 643 of the platform hanging on its bearing rope, the tilting elements and railings first on the lower landing, and the rope guides are installed, and the tilting elements of considerable length are connected with the rope lashings attached to the load-bearing poles, and the tilting elements on the higher levels are opened , and after unfolding each of the tilting elements at individual levels, they are secured with bolts. 9. The method according to p. 8. The method according to claim 8, characterized in that the suspension platform with the multi-leg sling connected to the rope of the suspension platform is lowered in the shaft directly to a predetermined height and the tilting elements are folded out. 10. The method according to p. 8. The method according to claim 8 or 9, characterized in that weights are inserted into the bearing pillar on the lower landing for static balancing of the platform.