RU2281439C1 - Lifting-rotatable exhaust device - Google Patents

Abstract

FIELD: ventilation.

SUBSTANCE: device comprises mechanism of double pivoting parallelogram. The parallelograms defined by the links of the mechanism are arranged in the parallel vertical planes for permitting mounting the section of the air duct between them. The air duct has two adjacent links mounted for permitting rotation in the vertical plane. The pivoting connection of the links comprises shaft whose ends are provided with radially oriented levers with different inclination. The levers are the links of the mechanism. The other links of the mechanism parallel to them are made in block with the cantilever mounted on the end section of the air duct arranged from the side of the unmovable base. The end section of the air duct is pivotally connected with the base through the rotatable base. The air duct has at least two flexible sections at the sites of the connection of the adjacent links of the air duct.

EFFECT: enhanced reliability and expanded functional capabilities.

11 cl, 10 dwg

Description

The invention relates to ventilation equipment and can be used for suction of dust and gas, as well as to remove harmful emissions directly from their places of formation.

A device for suctioning dust, gas, etc. is known. directly from the places of their formation, including an air intake device attached to a duct fixed to the support bracket, the links of which are connected by hinges (ed. St. SU No. 386211, IPC F 24 F 13/02, 1973). Each of the hinges of the duct is made in the form of a flexible insert having clamps at the ends connected with each other by means of earrings, one of which has a vertical rod pivotally attached to the rod with a counterweight mounted on it. Each insert is stretched by its edges to sections of pipelines and pressed by clamps using bolts, and then the earrings are connected by two axes, forming a hinge.

However, the known device has increased weight and size characteristics and limited operational capabilities, in particular, the features of the known device do not imply the possibility of its use as part of a moving filter unit.

A device is known for suctioning hazards according to ed. St. SU No. 821854 (IPC ³ F 24 F 7/06, B 08 B 15/02, 1981). The known device comprises an air intake connected to an air duct provided with a counterweight system and having pivotally connected swivel links. Swivel links are interconnected using telescopic racks mounted on them, one of which is equipped with a thrust bearing. Another rack is equipped with a bolt resting on said thrust bearing. The counterweight system is made in the form of separate rigid consoles with weights mounted on the links of the ducts.

However, the known device, as well as the above device, has increased weight and size characteristics, in particular, this is due to the presence of a counterweight system in the form of separate rigid consoles with weights fixed to the links of the duct. In addition, the known device has elements that "obscure" the duct, which creates obstacles to the movement of gases in the duct.

An exhaust device according to patent RU No. 2059934 (IPC ⁶ F 24 F 7/06, 1996) is also known. The known device comprises an air intake, an exhaust duct with a rotary support and a support pipe, a supporting mechanism having lever links connected to each other, an air intake and a support pipe by means of hinges, and a spring attached at one end to the support pipe in a diametrically opposite side from the lever. All hinges are made in the form of friction pairs with elements that regulate the force of their mutual rotation. The spring at the other end is fixed directly to the starting link. The longitudinal axis of the spring is located in the plane of movement of the initial link. In an embodiment, the spring on the initial link is fixed with the possibility of regulating the tension force, and the air intake is connected to the final link through the Hook joint.

A disadvantage of the known device is the "shading" of the duct support mechanism.

A welding gas remover manufactured by AFA Abgasförderanlagen GmbH is also known (see brochure Abgasförderanlagen. Always Fresh Air, p.10). The known device (hood) contains a ventilation sleeve, one end portion of which is connected to the air intake, and the other with the possibility of communication with the motive is pivotally mounted on a stationary base with the possibility of rotation around a vertical axis. The device is positioned using a powerful single parallelogram lever design with an external parallelogram. Holding the parallelogram in any installed free position is achieved by gas-filled dampers (gas springs). In such hoods there are no obstacles to the movement of gases in the ventilation sleeve, as a result of which the maximum volume of exhaust gases is achieved. The lever system includes a bracket for wall or ceiling mounting. The air inlet is equipped with an air damper.

The disadvantages of the known device include the fact that the corrugated ventilation sleeve in comparison with a smooth duct creates a greater aerodynamic drag. In addition, the device does not imply the possibility of extending the air intake to the full length of the ventilation sleeve, because in the extreme positions of the articulated parallelogram mechanism, a parallelogram can transition to antiparallelogram. As a result, the movement zone of the air sleeve with the air receiver is structurally limited.

The closest set of essential features with the claimed invention is a lifting and rotary exhaust device containing an air duct including articulated links, one end section of which is pivotally connected to the air intake, and the other with the possibility of communication with a collector (inducer) is pivotally mounted on a fixed base with the possibility of rotation relative to the vertical axis, and a counterweight system with cargo (ed. St. SU No. 1231326 A1, IPC ⁴ F 24 F 7/06, 1986). The air duct is equipped with an additional link having a latch with a drive and installed between the air receiver and the first swivel link of the air duct with the possibility of axial movement relative to the latter. The swivel links of the duct are interconnected by means of a flexible insert and eyes fixed to the swivel links and interconnected by axes. The counterweight system is installed on the first in the air passage of the duct and is equipped with an additional load mounted on the lever with the ability to move and connected on one side with a tension spring, and on the other with a flexible cable and a system of blocks with an additional link.

However, the known device has limited functionality, because the movement zone of the duct with the air intake is structurally limited, in particular, by the features of the counterweight system. In addition, the cable block system used for axial movement of an additional duct link is rather complicated, which reduces the reliability of the device. Along with this, the device does not imply providing automatic fixation of the position of the additional link in space, which complicates the maintenance of the device.

The objective of the present invention is to provide a lifting and swivel exhaust device that provides ease of movement and fixation, as well as ease of maintenance during operation and adaptability to various installation options.

This problem is solved due to the fact that the lifting and swivel exhaust device containing an air duct including articulated links, one end section of which is pivotally connected to the air receiver, and the other with the possibility of communication with a motive, is pivotally mounted on a stationary base with the possibility of rotation about a vertical axis , and means for balancing the duct, and the duct is made with a flexible section located at the hinge of adjacent links ozduhovoda according to the invention comprises a double hinge mechanism of a parallelogram. The parallelograms formed by the links of the mentioned mechanism are located in parallel vertical planes with the possibility of placing a duct section between them. The duct includes two adjacent links mounted with the possibility of rotation in a vertical plane. The hinge connection of the latter includes a shaft, at the ends of which, with different tilts, radially arranged levers are rigidly fixed, which act as links of the double hinged parallelogram mechanism. Other links of the double hinged parallelogram mechanism, located respectively parallel to the mentioned links, are structurally combined each with a bracket mounted on the end section of the duct located on the side of the fixed base. The end section of the duct is pivotally mounted on said stationary mounted base by means of a rotary base, which is mounted on a fixed mounted base with the possibility of rotation together with the duct around said vertical axis. In this case, the duct has at least two flexible sections located at the joints of the articulated joints of the adjacent duct links.

Along with this, the rotary base is equipped with two spaced apart bearing bearings located outside the duct, one of the bearing bearings being made in the form of rolling bearings, and the other a sliding bearing.

In addition, the duct relative to the rotary base is installed with the possibility of limited rotation around the vertical axis.

In this embodiment, the lifting-rotary exhaust device may be equipped with a friction mechanism that is installed between the rotary base and the duct and includes elements that control the force of mutual rotation of the latter.

At the same time, the lifting and turning exhaust device is equipped with an air damper installed inside the duct from the side of the air intake with the possibility of rotation about the axis orthogonal to the longitudinal axis of the corresponding section of the duct.

In addition, as a means of balancing the duct, the lifting and exhaust device comprises articulated gas springs that are each mounted with the possibility of changing their position relative to the duct.

In the latter embodiment, the lifting and turning exhaust device includes two identical gas springs, each of which is installed between a link made in the form of a traction mechanism of a double articulated parallelogram and said bracket mounted on an end section of an air duct located on the side of the stationary base, as well as a third gas a spring, which is installed between the link of the duct connected to the air receiver and the lever rigidly mounted on the said shaft. At the same time, the lever connected to the third gas spring is made in one piece with the lever acting as a link of the double hinged parallelogram mechanism.

At the same time, a gap in the light is formed between the cut of the duct and the cut of the reciprocal duct of the end part of the fixed base. The said gap on the outer side of the duct is closed by a sealing shell of elastic material, which is mounted on the duct and partially overlaps the outer duct of the end part of the fixed base.

In addition, the end sections of the two adjacent duct links at the junction with the flexible sections of the latter in cross section have each kind of ring, pressed down in the vertical direction.

Swivel joints of adjacent duct links mounted to rotate in a vertical plane contain friction pairs with elements that control the force of mutual rotation of the duct links.

At the same time, the two adjacent duct links are interconnected using brackets rigidly fixed at the ends of these links, pivotally mounted with through holes made on the brackets on said shaft between the levers, which act as the links of the double hinged parallelogram mechanism, and interacting with each other through washers mounted on the same shaft from antifriction material.

In addition, said shaft is detachable.

The technical result of the use of the invention lies in the fact that it provides the expansion of the service area, facilitating the movement of the duct in space and extends the operational characteristics of the lifting-rotary exhaust device. Along with this, the invention improves the reliability of the lifting-rotary exhaust device.

Figure 1 schematically shows a lifting and rotary exhaust device, General view, an embodiment when the device is mounted on top of a horizontally located supporting surface; figure 2 is the same embodiment, when the device is mounted from below a horizontally located supporting surface; figure 3 - lifting-rotary exhaust device with the extreme position of the links of the duct, General side view; figure 4 is the same, the relative position of the links of the double hinged parallelogram mechanism, a general view of the other side of the duct; figure 5 - bearing rotary base and the device of the friction mechanism installed between the rotary base and the duct, a longitudinal section, element a in figure 1; in Fig.6 - another bearing support of the rotary base and the sealing device of the gap between the cut of the duct and the cut of the reciprocal duct of the end part of the stationary base, longitudinal section, element B in figure 1; in Fig.7 - device swivel adjacent parts of the duct, a cross section along BB in Fig.3; on Fig - device swivel adjacent parts of the duct, a cross section along G-G in figure 3; figure 9 - air damper installed inside the duct link, a cross section along DD in figure 4; figure 10 - the device is a planar swivel of the duct, cross section, element E in figure 3.

The lifting and swivel exhaust device comprises an air duct including articulated links 1-4. Adjacent links 2 and 3 of the duct are mounted to rotate in a vertical plane. One end section of the duct is connected to the air inlet (intake funnel) 5, and the other with the possibility of communication with a driver (for example, exhaust ventilation system, fixed or movable filter) is pivotally mounted on a fixed base 6 by means of a rotary base 7. The rotary base 7 is mounted on the base 6 with the possibility of rotation together with the duct around the vertical axis 8. In this case, the rotary base 7 is equipped with two spaced apart bearings 9 10 arranged outside the duct. Bearing support 9 is made in the form of rolling bearings, for example, in the form of a double angular contact bearing. Bearing support 10 is made in the form of a sliding bearing, including ring elements (gaskets) 11 of a material with a low coefficient of friction, for example fluoroplastic.

Between the cut "a" of the duct (essentially a cut of the end part of the link 1 of the duct) and the cut "b" of the reciprocal duct of the end part of the base 6, a gap in the light is formed. This gap on the outside of the duct is covered by a sealing shell 12 of elastic material, such as rubber. The shell 12 is mounted on the end of the link (outlet) 1 of the duct and partially overlaps the return duct of the end part of the base 6. In an embodiment of the invention, the shell on the duct is secured, for example, using a clamp (not shown).

In an embodiment of the invention, the duct is made with flexible sections 13 and 14 located respectively in the places of articulation of the link 1 of the duct with the link 2 and the latter with the link 3 of the duct. Flexible sections are made in the form of corrugated flexible hoses equipped with a metal spiral, for example, from polyvinyl chloride. Variants of flexible sections in the form of a fabric or metal-fabric hose with a metal or plastic spiral are possible. In another embodiment, the duct can also be made with a flexible section located at the place of articulation of the duct with the air inlet 5 (not shown). An embodiment of the device in which the air inlet is connected to the duct through a rigid outlet is preferred when the exhaust device is used in manufacturing, for example, welding or abrasive metal processing.

The lifting and swivel exhaust device comprises a double articulated parallelogram mechanism 15. The parallelograms formed by the links of the mentioned mechanism are located in parallel vertical planes with the possibility of placing a duct section between them (essentially a rotary link 2 of the duct). The swivel of adjacent links 2 and 3 of the duct includes a shaft 16. In an embodiment, to ensure the installation of a swivel of links 2 and 3, the shaft 16 is made detachable. At the ends of the shaft 16 with different slopes, radially arranged levers 17 and 18 are rigidly fixed (for example, welded), which act as links of the double articulated parallelogram mechanism. Other links of the double articulated parallelogram mechanism, located respectively parallel to the mentioned links, are structurally combined with the bracket 19 mounted on the link (outlet) 1 of the duct. Due to this design of the double-hinged parallelogram mechanism, the uncertainty of movement in the extreme positions of the parallelogram mechanism is eliminated when the link 2 of the duct rotates in a vertical plane (i.e., in the extreme positions of the mechanism, the parallelogram does not transition into antiparallelogram).

Adjacent links 2 and 3 of the duct are interconnected using brackets 20 and 21, rigidly fixed (for example, by welding), respectively, on the links 2 and 3 of the duct. Through-holes are made in the brackets 20 and 21, with the help of which the brackets are pivotally mounted on the shaft 16 between the levers 17 and 18, which act as links of the double hinged parallelogram mechanism. The brackets 20 and 21 interact with each other through washers (gaskets) 22 mounted on the shaft 16 in the same way as the brackets. Washers 22 are made of antifriction material, for example fluoroplastic. In an embodiment, the end sections of the duct sections 2 and 3 at the junction with the flexible duct sections 13 and 14 in cross section have each type of ring pressed in the vertical direction (a cross section resembling an ovoid). This makes it possible to reduce the required radius of rounding for a flexible section of the duct, which reduces the weight and size characteristics of the respective nodes of the swivel and the duct as a whole. As a result, the magnitude of the force required to move the lifting-rotary exhaust device in space is reduced.

In an embodiment, the adjacent links 1-3 of the duct are connected in series using swivel joints containing friction pairs with elements that control the force of mutual rotation of these links of the duct. In this case, the adjacent links 1 and 2 of the duct are connected using brackets 19 and 23, rigidly fixed (for example, by welding), respectively, on the links 1 and 2 of the duct. The swivel connection of these air duct links includes an axis 24. Through the brackets 19 and 23, through holes are made through which the brackets are pivotally mounted on the axis 24. On the axis 24, friction washers (gaskets) 25 are installed in the same way, through which the brackets 19 and 23 interact with each other with a friend. The brackets 19, 23 and friction washers 25 are mounted on the axis 26 with preload, for example, Belleville springs 26 by means of a screw-nut pair, where the axis 24 serves as a screw. The hinged connection of adjacent links 2 and 3 includes a corresponding friction washer 25 through which the lever 18 interact performing the role of a link mechanism of a double hinged parallelogram, and the bracket 21, mounted on the link 3 of the duct. The bracket 21, the lever 18 and the friction washer 25 are mounted on the shaft 16 with compression, for example, by a corresponding disk spring 26 by means of a screw-nut pair, where the shaft 16 serves as a screw. The compression force of the disk springs 26 is adjusted in a fully assembled device so that the lifting the rotary exhaust device was easily moved in space and its position would be fixed after the cessation of movement.

In an embodiment of the invention, the duct relative to the rotary base 7 is installed with the possibility of limited rotation around axis 8, for example, at an angle of 180 °. The lifting-rotary exhaust device in an embodiment is equipped with a friction mechanism that is installed between the rotary base 7 and the air duct and includes elements that control the force of mutual rotation of the latter. Mentioned friction mechanism includes rigidly mounted on the bracket 19 mounted on the link (branch) 1 of the duct, element 27. On the element 27 is made a through groove, which is located around the circumference relative to axis 8. Through the groove is passed a rod element 28, which is mounted with vertical movement on the rotary base 7. Friction washers 29 are installed on the rod element 28, interacting with the element 27. Friction washers 29 are installed with the belleville springs 30 pressed against the element 27 by means of pairs screw-nut, wherein the screw is a rod member 28. The rotation angle of the rotary duct with respect to the base 7 is restricted, the groove formed on the element size of 27.

The lifting and swivel exhaust device comprises means for balancing the duct. In an embodiment of the invention, the device comprises pivotally mounted gas springs 31, 32 as such means. The latter are each mounted with the possibility of changing their position (i.e., with the possibility of reinstallation) relative to the air duct to create the necessary moment of unbalanced moment from the weight of the corresponding part of the air duct. Gas springs 31 are each installed between the corresponding link of the double articulated parallelogram mechanism in the form of a thrust 33 and the bracket 19. The gas spring 32 is installed between the duct link 3 and the lever rigidly fixed (for example, by welding) to the shaft 16 and made in one piece with the lever 18, performing the role of a link mechanism of a double articulated parallelogram. Thus, the lever 18 is essentially a two-arm lever, one arm of which is pivotally connected to a rod 33, which is a link of the double articulated parallelogram mechanism, and the other is pivotally connected to a gas spring 32. The position of each gas spring 31 is pivotally connected with the corresponding tip of the gas spring of the slider 34, moving along the vertically oriented groove "c", made in the bracket 19. The position of the gas spring 32 is changed analogously chnym manner by a respective slider 34, moving along the vertically oriented groove "d", made in a double-arm lever 18. In the fully assembled device inaccuracy equilibration pivot in the vertical plane of the duct elements is compensated using said frictional washers 25.

The lifting and rotary exhaust device is also provided with an air damper 35 mounted inside the duct link 3 with the possibility of rotation relative to the axis 36 orthogonal to the longitudinal axis of the duct component 3 using the handle 37. Due to this, when using several exhaust devices connected to a single local exhaust network ventilation, it is possible to work only that exhaust device, which is installed in the place where they are currently doing the work.

The air intake (intake funnel) 5 is connected to the rotary link 3 of the duct through the link (outlet) 4 of the duct by plane hinges 38 and 39 located in two planes at an angle, for example, 45 ° to each other. For ease of handling, a lifting and swivel exhaust device is provided with a handle 40.

Installation and fastening of the lifting-rotary exhaust device in a regular place is carried out by means of a flange “e” of the base 6 using threaded elements (not shown). In an embodiment of the invention, a lifting and swivel exhaust device is mounted on a horizontally arranged supporting surface (for example, the surface of a table, wall bracket, floor filter unit) from above. In another embodiment, the lifting and swiveling device can be mounted on a horizontally located surface (for example, the surface of a wall bracket, cantilever duct, wall filter unit) from the bottom. Compared with the first option, this option involves mounting the brackets 20, 21 and the gas spring 32 from the diametrically opposite side of the duct (as shown in the drawing above). To enable mounting of the double hinged parallelogram mechanism in this embodiment, the corresponding through-hole coaxial holes “f” for the hinges associated with rods 33 are provided in the bracket 19.

Lift-rotary exhaust device operates as follows. After the complete assembly of the device for the preliminary balancing of the rotary elements of the air duct in the vertical plane, the links 2 and 3 of the air duct assembly with the link (outlet) 4 of the air duct and the air intake 5 are set to a position close to vertical. In this position, gas springs 32 and 31 are sequentially installed and fixed in the free state on the air duct. Then, the rotary links of the air duct are moved to a horizontal position and their final balancing is performed. After that, in the fully assembled device, the compression force of the Belleville springs 26, respectively mounted on the axis 24 and the shaft 16 in the swivel joints, which rotate the duct elements in a vertical plane, is regulated. The compression force of the Belleville springs 26 is regulated so that the links 2 and 3 of the duct easily moved in space by the effort of human hands and their position would be fixed after the cessation of movement. The compression force of the Belleville springs 30, mounted on the rod element 28 of the friction mechanism installed between the rotary base 7 and the link (tap) 1 of the duct, is regulated. The compression force of the Belleville springs 30 is regulated so that the effort of the hands of a person easily rotates around the axis 8 relative to the rotary base 7 within a structurally defined angle (for example, 180 °).

When the lifting-and-turning device is operated from the efforts of human hands, the air duct with the air inlet 5 moves to any point in space limited by the radius of the airflow around the air duct, pivotally turning on the base 6 around axis 8, as well as in the connection points of adjacent duct links, respectively, relative to axis 24 and relative to shaft 16 The air inlet 5 is rotated by the efforts of human hands with the help of plane hinges 38, 39 over any point of formation of harmful substances in the indicated space.

When the device is operating, the moment of force from the weight of the link 3 of the duct with the tap (link) 4 and the air intake 5 is largely balanced by a gas spring 32 installed between the link 3 of the duct and the lever rigidly mounted on the shaft 16 and made in one piece with the lever 18, performing the role of the link mechanism of the double articulated parallelogram. The inaccuracy of balancing is compensated by the friction washer 25, which is located between the bracket 21 and the lever 18. Thus, the friction moment when the link 3 of the duct is rotated relative to the axis of the shaft 16 is only partially transmitted to the link 2 of the duct through the bracket 20 and the washer 22 of antifriction material. This facilitates the movement of the link 3 of the duct relative to the link 2 of the duct. The moment of force from the weight of the link 2 of the duct with the elements of the double articulated parallelogram mechanism and the moment of force from the weight of the vertically arranged link 3 of the duct with the outlet (link) 4 and the air intake 5 is largely balanced by gas springs 31. The inaccuracy of the balancing is compensated by friction washers 25 mounted on the axis 24 swivel of adjacent links 1, 2 of the duct. Since the change in the position of the link 3 of the duct with the outlet (link) 4 and the air intake 5 relative to the vertical does not cause a change in the moment in the hinge of adjacent links 1 and 2 of the duct, the braking moment in this hinge may be smaller than in the case when the balancing of the link 3 the duct is not carried out.

Due to the particular design of the double-hinged parallelogram mechanism, motion uncertainty in the extreme positions of the parallelogram mechanism is eliminated when the link 2 of the duct rotates in a vertical plane (in the extreme positions of the mechanism, the parallelogram does not go into antiparallelogram), which increases the reliability of the device.

When the influence of the efforts of the hands ceases, the air receiver is fixed in the position given to it due to the balancing of the duct elements with gas springs 31, 32 and selected minimum necessary friction in the articulated joints. In the horizontal plane, fixing the position of the duct is provided by the frictional force in the bearing support 10. Together with this, using the friction mechanism that is installed between the rotary base 7 and the duct, the position of the duct relative to the rotary base 7 is fixed.

In real conditions, the lifting and turning exhaust device in the horizontal plane during operation rotates mainly, usually within a limited angle. In the claimed device, said rotation is ensured, in particular, by a rolling bearing installed in the bearing support 9. In this case, the air duct rotates around axis 8 relative to the rotary base 7. If necessary, turn it at a larger angle (for example, when using a lift-rotary exhaust device in the composition of a floor filter unit) a sliding bearing is installed in the work, mounted in the bearing support 10, which allows rotation around axis 8. Moreover, through the rod element 28, the rotation of the duct (link 1 of the duct) around the axis 8 is transmitted to the rotary base 7, and the rotary base 7 rotates together with the duct around the axis 8 relative to the base 6. Under real operating conditions, the sliding bearing installed in the bearing support 10 is included in the operation less frequently than a rolling bearing installed in the bearing support 9. This is a circumstance, as well as the fact that the sliding bearing is installed outside the duct (i.e. removed from the flow of polluted air), allows to increase the durability of the sliding bearing. Moreover, the specified bearing can be made of relatively inexpensive materials and can work without lubrication. At the same time, the features of the structural design of the device (in particular, the features of the mutual arrangement of the base 6, the rotary base 7 and the link 1 of the air duct with bearing bearings spaced apart in height and located outside the air duct) make it possible to use small standard and relatively inexpensive rolling bearings for the bearing support 9. This ensures ease of rotation of the duct around axis 8, ease of maintenance of bearing bearings and increases the reliability of the bearings and, therefore, the device as a whole.

Thus, due to the particular design of the lifting-rotary exhaust device, the invention provides an extension of the service area, facilitating the movement of the duct in space and extends the operational characteristics of the lifting-rotary exhaust device. Along with this, the invention increases the reliability of the lifting-rotary exhaust device and allows to reduce its weight and size characteristics.

Claims (12)

1. A lifting and rotary exhaust device containing an air duct including articulated links, one end portion of which is pivotally connected to the air receiver, and the other with the possibility of communication with a motive device is pivotally mounted on a stationary base with the possibility of rotation relative to the vertical axis, and means for balancing the air duct moreover, the duct is made with a flexible section located at the hinge of adjacent parts of the duct, characterized in that it contains t is a double hinged parallelogram mechanism, the parallelograms formed by the links of the said mechanism are arranged in parallel vertical planes with the possibility of placing a duct section between them, the duct includes two adjacent links mounted for rotation in a vertical plane, the hinged connection of the latter including a shaft, at the ends of which, with different slopes, radially arranged levers are rigidly fixed, which act as links of the double hinge mechanism second parallelogram, while the other links of the latter, arranged respectively parallel to the mentioned links, are structurally aligned each with a bracket mounted on an end section of the duct located on the side of the fixed base, and the end section of the duct is pivotally mounted on the stationary fixed base by means of a rotary base, which mounted on a permanently installed base with the possibility of rotation together with the air duct in pyr said vertical axis, wherein the duct has at least two flexible portion disposed at places of articulation of adjacent links of the duct. 2. The device according to claim 1, characterized in that the rotary base is equipped with two spaced apart bearing bearings located outside the duct, one of the bearing bearings being made in the form of rolling bearings, and the other a sliding bearing. 3. The device according to claim 1, characterized in that the duct relative to the rotary base is installed with the possibility of limited rotation around the vertical axis. 4. The device according to claim 3, characterized in that it is equipped with a friction mechanism that is installed between the rotary base and the duct and includes elements that control the force of mutual rotation of the latter. 5. The device according to claim 1, characterized in that it is equipped with an air damper mounted inside the duct from the side of the air intake with the possibility of rotation about the axis orthogonal to the longitudinal axis of the corresponding section of the duct. 6. The device according to claim 1, characterized in that as means for balancing the duct it contains articulated gas springs that are mounted each with the possibility of changing its position relative to the duct. 7. The device according to claim 6, characterized in that it includes two identical gas springs, each of which is installed between a link made in the form of a traction mechanism of a double hinged parallelogram and said bracket mounted on an end section of the duct located on the side of the stationary base, as well as a third gas spring, which is installed between the duct link connected to the air intake, and a lever rigidly fixed to the said shaft, while connected to the third gas the spring lever is made in one piece with the lever, acting as a link in the mechanism of the double articulated parallelogram. 8. The device according to claim 1, characterized in that between the cut of the duct and the cut of the reciprocal duct of the end part of the fixed base, a gap is formed in the light, said gap on the outside of the duct being closed by a sealing shell of elastic material that is fixed to the duct and partially overlaps from the outside, the return duct end part of a fixed base. 9. The device according to claim 1, characterized in that the end sections of the two adjacent adjacent duct links at the junction with the flexible sections of the latter in cross section have each type of ring pressed in the vertical direction. 10. The device according to claim 1, characterized in that the swivel joints of adjacent duct links mounted to rotate in a vertical plane contain friction pairs with elements that control the force of mutual rotation of the said duct links. 11. The device according to claim 1, characterized in that the said two adjacent duct links are interconnected by means of brackets rigidly fixed at the ends of these links, pivotally mounted with through holes made on the brackets on said shaft between the levers acting as the links of the double mechanism articulated parallelogram, and interacting with each other through washers of antifriction material mounted on the same shaft. 12. The device according to claim 1, characterized in that said shaft is detachable.

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