RU170994U1 - Telescopic mast - Google Patents

Abstract

The telescopic mast (TM) is designed to install a payload on it with the goal of quickly raising / lowering this load to a predetermined height. The utility model can be used in antenna technology, as well as for solving problems of video surveillance, lighting, etc. The characteristic features of the TM are that its sections are formed by profiled vertical posts with a straight lateral generatrix, located axisymmetrically, and the adjacent sections are arrayed with their racks mutually rotated around the axis, and the elements of the lower and upper centering and locking from rotation around the axis of each movable section are associated with vertical racks of an adjacent section along their profile with the possibility of shifting this movable section in the axial direction.

Description

The utility model relates to telescopic telescopic masts, which are designed to install a payload on them (equipment for one purpose or another) with the goal of promptly raising / lowering this load to a given height. The technical solution can be used in antenna technology, as well as for solving the tasks of video surveillance, lighting and monitoring of law and order at mass celebrations, sporting events, concerts, including for operational anti-terrorism control.

A technical solution of the telescopic mast is known, which is described in the patent application US 5593129 A, 01/14/1997, in which the mast is formed by a fixed outer, movable intermediate and inner tubular sections with elements of internal and external alignment, which are interconnected by movable key joints, preventing rotation of the sections around the central axis and providing the possibility of telescoping sections. The bottoms in the lower parts of the movable sections are made in the form of nuts spring-loaded on one side, which interact with the lead screw of the translational displacement drive. On the basis of the lead screw located coaxially to the mast sections, a groove is made to accommodate the nuts in their initial position (the mast is folded in this state). In the folded position of the mast with the thread of the lead screw, only one nut of the inner section is engaged, the remaining nuts are located in the groove of the lead screw and do not interact with its thread. On the upper part of each section there are installed locks for the mutual axial fixation of adjacent sections and mechanisms ensuring the operation of these locks in the extreme telescoping positions of these sections. This analogue has a number of disadvantages, among which can be called a significant windage and mast weight, which is due to the use of continuous tubular sections. The mast in the unfolded state is characterized by significant radial backlash of the sections and the accompanying angular pitching, due to the fact that the sections are mutually centered on cylindrical surfaces with a certain gap, which is necessary to ensure their relative movement. The elements of securing the sections against rotation around the axis, made in the form of movable keyed joints between adjacent sections, are also unreliable, since the keyways and keys are located in narrow slotted annular spaces of adjacent sections, which leads to their minimum mating area and, therefore, their insufficient reliability under intensive and long-term operation of the product.

A technical solution of the telescopic mast is known, which is described in the patent specification for the group of inventions US 7497140 B2, 03.03.2009. According to the structure and basic principle of operation, this analogue does not differ from the solution according to patent US 005593129 A. In accordance with paragraphs. 1-21 formulas, it differs from its analogues by the presence of a friction brake in the translational drive, the design of the key connection of adjacent sections and the presence of axial springs, with the function of two-sided shock absorption of nuts in the axial direction, and also that the mast sections are made of carbon fiber (as an option) . In paragraphs 22-31 of the formula, the patent protects the design of the locks of the mutual axial fixation of adjacent sections and the mechanisms that ensure the operation of these locks in the extreme positions of the telescoping sections. This analogue is fully characterized by the disadvantages indicated above for the analogue of US Pat. No. 5,593,129 A.

The prototype of the utility model is the design of a telescopic mast according to patent RU 2198131, 02/10/2003. This technical solution according to the principle of operation and design of the telescoping sections drive is similar to the previous analogues considered. The specified patent protects the design of locks for mutual axial fixation of adjacent sections and the mechanisms that ensure the operation of these locks in the extreme positions of telescoping sections. According to the description and drawings, the expanded state locks are located outside, in the upper parts of the intermediate sections. The bevels are made on them. The latches are provided with a compression spring and correspond to mating holes in the lower parts in the corresponding previous movable sections, including the inner one. The mechanism for turning off the expanded state lock comprises a bracket mounted on each intermediate section next to the section having the expanded state lock latch, as well as on the outer section, and having a bevel for interacting with the bevel made on the corresponding latch. Folded locks are located in the upper parts of the intermediate and external sections and exclude the movement of more than one section. Each contains a swing arm with a grip and a torsion spring. The mechanism for turning off each lock of the folded state includes a pusher with a bevel installed inside the upper part of each intermediate section with the possibility of interaction with the lever of the corresponding lock of the folded state, and a bar with a bevel installed on the outer lower part of each previous movable section. In order to reduce the angular backlash of the mast in the azimuthal plane, the holes for approaching the latches of the expanded state locks in the fixed sections are made conical, and the entrance part of the latches is in the form of truncated cones. The prototype telescopic mast is equipped with limit switches of extreme positions, which are located outside the telescopic sections. The prototype is fully characterized by the disadvantages indicated for the analogues considered earlier, but, in addition, it has increased radial dimensions due to the arrangement of the lock elements of the axial mutual locking of adjacent sections and mechanism elements, which ensure that these locks operate in the extreme positions of the telescoping sections, as well as both limit switches - on the outer surfaces of the tubular sections.

The utility model aims to solve the problem of improving the design of a telescopic mast (TM) with an electromechanical drive so that this design meets its purpose and the state of the art to the maximum extent possible.

When using a utility model, the following set of useful technical results is achieved:

1. Decrease in material consumption and design weight of TM.

2. An increase in stiffness and a decrease in the radial backlash of the TM sections in the unfolded state.

3. Reducing the radial dimensions of the TM.

4. Increase the reliability of TM.

The essence of the utility model lies in the fact that the telescopic mast (TM) contains a base and a drive mounted on the base with a vertical lead screw, on which a groove is made to accommodate the nuts, contains two limit switches and contains at least three axial screws, telescopically embedded in one another section. The outer section is fixedly fixed at the base, and the remaining sections are mounted with the possibility of mutual movement - telescoping along their common central axis, each movable section is equipped with lower and upper centering elements and elements for fixing it against rotation around the axis, the elements of the mutual locks are installed on the upper part of each section axial fixation of adjacent sections with the possibility of the operation of these locks in the extreme positions of the telescoping sections, and the lower part of each movable section is equipped with an axial th screw and amortized on a nut axis.

At the same time, the utility model, in comparison with the known technical solutions of analogues, is a construction that has the following essential distinguishing features:

- the stationary section is formed by profiled vertical struts with a rectilinear lateral generatrix, located axisymmetrically, in an amount of at least two, reinforced with its lower part at the base, and the upper part - in the upper sleeve of this section;

- each movable section is formed by profiled vertical struts with a rectilinear lateral generatrix, located axially - symmetrically, in an amount of at least two, reinforced with its lower part in the lower sleeve of this section, and the upper part - in the upper sleeve of this section;

- adjacent sections with arrays of their racks are mutually deployed around the axis;

- elements of lower centering and fixation from rotation around the axis of each male movable section are fixed in its lower sleeve and mated with vertical posts of an adjacent female section along their inner profile with the possibility of shifting the male section in the axial direction;

- the elements of the upper centering and locking against rotation around the axis of each male movable section are mounted in the upper sleeve of the adjacent female section and mated with the vertical struts of the male section along their external profile with the possibility of shifting the male section in the axial direction.

In FIG. 1 shows a general view of a TM consisting of a stationary outer and two movable sections in a folded state.

In FIG. 2 shows a general view of a TM consisting of a stationary outer and two movable sections in the unfolded state.

In FIG. 3 shows a section AA illustrating the shape and relative position of the vertical struts forming the outer section of the TM.

In FIG. 4 is a section B-B illustrating the construction of the elements of the lower centering and fixation from rotation around the axis of the movable middle section of the TM.

In FIG. 5 shows a cross-section EE, further explaining the design of the elements of the lower centering and fixation from rotation around the axis of the movable middle section of the TM.

In FIG. 6 shows a section G-G, explaining the design of the elements of the lower centering and fixation from rotation around the axis of the movable inner section of the TM.

In FIG. 7 shows a section Zh-Zh, further explaining the design of the elements of the lower centering and fixation from rotation around the axis of the movable inner section of the TM.

In FIG. 8 is a section BB illustrating the structure of the upper centering and locking elements from rotation about the axis of the movable middle section of the TM.

In FIG. 9 shows a section DD, explaining the design of the elements of the upper centering and fixation from rotation around the axis of the movable inner section of the TM.

In FIG. 10 shows a fragment of the structures of the movable middle and inner sections of the TM, in which the vertical posts are interconnected by rigid jumpers made in the form of ring segments of sheet material

In FIG. 11 shows a section ZZ, explaining the construction of rigid jumpers made in the form of annular segments of sheet material.

The telescopic mast (TM) contains a base (1), mounted on the base of the drive (2) with a vertical lead screw (3), on which a groove (4) is made and contains three axial screws telescopically embedded in one section (Fig. 1 and 2). The outer section (5) is fixed at the base (1), and the movable middle (6) and the movable inner section (7) are mounted with the possibility of mutual movement - telescoping along their common central axis. This feature is provided by the design of the TM, in which the outer section (5) is formed by three identical vertical posts (8) with a rectilinear lateral generatrix and a U-shaped cross section (channel), which are located axisymmetrically with a mutual turn of 120 angular degrees (Fig. 2- four). The cross section may have a different cross-sectional shape, different from the channel, at which this cross section has sufficient axial resistance moments to ensure the strength and vertical stability of the strut (8) under load. So, the indicated section may take the form of a T-shaped (Taurus), arched (trough) or other, i.e. polygonal shape. As a material for the manufacture of racks (8), structural ferrous or non-ferrous metal, plastic, as well as a modern composite structural material, for example carbon fiber, can be used. Each post (8) is strengthened by its lower part in the base (1), and the upper part in the upper sleeve (9) of the fixed outer section (5). The middle movable section (6) as well as the outer section (5) is formed by similar three vertical uprights (10) with a rectilinear lateral generatrix and identical cross section, which are located axisymmetrically with a mutual turn of 120 angular degrees (Fig. 2, 4, 5). Each post (10) is reinforced with its lower part in the lower sleeve (11) of this section, and the upper part in the upper sleeve (12) of this section. The array of vertical struts (10) of the middle movable section (6) is deployed relative to the array of vertical struts (8) of the outer section (5) by 60 angular degrees, which corresponds to the formula according to which in general the angle of rotation of the struts in adjacent sections is 360 ° / 2N where N is the number of racks in the section. On the lower sleeve (11) of the middle movable section (6), three elements of lower centering and fixing against rotation of the section (6) around the axis are made, made in the form of identical protrusions (13) that mate with the uprights (8) along their inner profile, with the possibility of shifting the middle movable section (6) in the axial direction (up / down) relative to the outer section (5) (Fig. 4 and 5). The protrusions (13) may be made of an antifriction material, for example, polyamide, or may be provided with an antifriction coating obtained, for example, by spraying technology. A similar design with reduced radial mounting dimensions has a movable inner section (7), formed by an array of identical vertical posts (14), mounted in the lower sleeve (15) and upper sleeve (16), and deployed by the indicated array relative to the array of vertical columns (10) of the middle the movable section (6) at 60 angular degrees (Fig. 2, 6, 7). On the lower sleeve (15) of the inner movable section (7), three lower centering and securing elements against rotation of the section (7) around the axis are made, made in the form of identical protrusions (17) identical to the protrusions (13) that mate with the uprights (10) ) along their inner profile, with the possibility of shifting the inner movable section (7) in the axial direction (up / down) relative to the middle movable section (6) (Fig. 6 and 7). In the upper sleeve (12) of the movable middle section (6), the lock elements (18) and (19) of the mutual axial locking of adjacent sections are identical for all sections with the possibility of these locks working in the extreme telescoping positions of the movable middle section (6). In the upper sleeve (9) of the outer section (5), only the lock elements (19) are installed, since there is no enclosing section for the section (5). The design of the elements of the locks (18) and (19) can be borrowed from the known analogues of TM. Elements of the upper centering and fixing of the middle movable section (6) from its rotation around the axis are made in the form of splines (20) in a washer (21), which is mounted on the upper sleeve (9) of the outer section (5), and the splines (20) are conjugated with vertical struts (10) of the middle movable section (6) along the outer profile of these struts with the possibility of shifting the middle movable section (6) in the axial direction (up / down) relative to the outer section (5) (Fig. 2 and 8). The washer (21) may be made of an anti-friction material, for example polyamide, or the slots (20) may be provided with an anti-friction coating. A similar design with reduced radial mounting dimensions has the upper sleeve (12) of the middle movable section (6), on which the washer (22) with splines (23) is mounted (Figs. 2 and 9). In the lower parts of the middle movable section (6) and the inner movable section (7), i.e. identical nuts (24) and (25) are installed in the lower bushings (11) and (15), axially to the lead screw (3), fixed from turning in the bushings with the same type of splines (26), shown by the same position for both nuts, and each the nut (24) and (25) is equipped with a pair of axial shock absorbers of the same type (27), also shown as one position (Figs. 1, 5, 7). The number of movable sections, similar in design to the middle movable section (6), in the telescopic mast can be any and is determined by its structural dimensions in the folded and unfolded states. The design of all movable sections differs only in radial mounting dimensions and, in addition, the inner (last) movable section (7), unlike the middle movable section (6), does not carry lock elements (18) and a washer similar to its upper sleeve (16) washers (21) and (22), since this section is internal and there is no male section for it. Particular embodiments of certain elements of a patented technical solution are possible. These options provide an additional contribution to the achievement of the claimed technical results without changing the essence of the utility model. So, in order to increase the rigidity of the TM supporting structure, the vertical struts in each section or in separate sections can be interconnected by rigid jumpers, which are made in the form of ring segments (28) and (29) made of sheet material and reinforced by welding or in another way on uprights, so that they do not interfere with the telescoping of the sections (Fig. 10 and 11). Within the framework of this feature, all TM sections or only some of them in the extreme case can be equipped with jumpers - ring segments (28) and / or (29), which connect the vertical posts (8), (10), (14) along the entire length of these sections, forming continuous pipes, with the exception of the zone of location of the elements of the locks (18). In this case, the vertical struts become similar to the power supporting spars in thin-walled pipes. In addition, the uprights (8), (10), and (14) of the sections (5), (6) and (7) can be located at the same acute angle in the range from 0 to 5 angular degrees with respect to their common central axis, and the vertex of this angle is directed upwards, i.e. the corresponding radial mounting dimensions of the uprights in the corresponding upper bushings (9), (12) and (16) can be made somewhat smaller compared to the radial mounting dimensions in the base (1) and in the corresponding lower bushings (11) and (15), which and provides the above acute angle. To protect the internal surfaces of the TM from atmospheric precipitation, as well as from dust and pollution, the mast sections can be equipped with separate corrugated protective elements or a common protective corrugated element made of rubber, rubber-textile material or other flexible flexible material (not shown).

The telescopic mast operates as follows. In the folded state, the nut (24) of the middle movable section (6), mounted in the lower sleeve (11), is located on the groove (4) of the lead screw (3) below the beginning of its thread and does not interact with the thread, and the nut (25) is internal movable section (7) is located on the thread of the lead screw (3) in its lower part, above the groove (4). When the drive (2) is turned on, the lead screw (3) begins to rotate, as a result of which the internal movable section (7) through the nut (25) and the sleeve (15) receives translational movement vertically upwards. In this case, the vertical posts (14) are centered and kept from the radial displacement by the slots (23) of the washer (22) in their upper part, and by the protrusions (17) on the lower sleeve (15), which are mated with the corresponding surfaces of the vertical posts, from the splines (23) 14) and (10). The locking devices with their elements (18) and (19), connecting the middle movable section (6) with the outer stationary section (5), block premature upward movement of the middle movable section (6), which could arise from the action of friction forces when the mating surfaces move racks (14) in the slots (23) and protrusions (17) in the racks (10). When the nut (25) reaches a position that brings it closer to the exit from the thread of the screw (3), which is approximately one and a half lengths of the threaded part of the nut (25) from the tip of the screw (3), the elements of the locking devices (18) and (19) release the connection section (6) with section (5) and connect section (7) with section (6), so then section (6) begins to move together with section (7), as a whole, vertically upward. Due to this movement, the nut (24) from the groove (4) is fed to the thread of the lead screw (3), after which two nuts (24) and (25) simultaneously move along the lead screw (3), in which the difference between the steps and the thread leads, due to inaccuracy in their manufacture and relative positioning, it is compensated by axial shock absorbers (27). Shock absorbers (27), unlike prone to breakage springs of the prototype, are made in the form of washers made of rubber or rubber-textile material, which increases the reliability of the device, i.e. contributes to the achievement of one of the claimed technical results. The absence of rotation of the nuts (24) and (25) in the bushings (11) and (15) is ensured by slots of the type (26). Further movement of sections (7) and (6) leads to the nut (25) coming off the lead screw thread (3), while sections (7) and (6) continue to move together, being connected together by elements of locking devices (18) and ( 19). The movement stops when the drive (2) is turned off, which, in particular, can be provided with a limit switch of the upper extreme position (not shown). Reversing the drive (2) will result in the rotation of the lead screw (3) in the opposite direction, as well as the reverse order of the above events and bringing the TM to its original (folded) state. In this case, turning off the drive (2), in particular, can be provided with a limit switch of the lower extreme position (not shown). Introduction to the design of sections of rigid jumpers (28) and / or (29) located between the vertical posts (8), (10) and (14) increases the structural rigidity of the telescopic mast, while the essence of the structure and the principle of its operation remains unchanged. A promising embodiment is the TM, in which the uprights (8), (10) and (14) of sections (5), (6) and (7) are located at an acute angle in the range from 0 to 5 angular degrees with respect to their total central axis, i.e. the corresponding radial mounting dimensions of the uprights on the upper bushings (9), (12) and (16) are slightly smaller than the mounting dimensions on the base (1) and the lower bushings (11) and (15). This option provides elastic jamming of the racks of each male movable section in the slots of the corresponding washer, which is installed on the upper sleeve of the adjacent female section, as well as elastic jamming (interference) of the lower centering elements and fixation of this male movable section in vertical racks of the same adjacent female section . This achieves an additional increase in stiffness and a decrease in the radial backlash of the TM sections in the unfolded state.

The essence of the utility model is associated with the claimed technical results as follows, respectively:

1. The reduction of material consumption and design weight is achieved by the fact that the stationary outer (5) and all movable sections (6) and (7) are formed by profiled vertical posts of the same type (8), (10), (14). The weight and material consumption of such sections compared with the tubular is much less.

2. An increase in stiffness and a decrease in the radial backlash of the TM sections in the unfolded state is achieved by the fact that the elements of the type (13) and (17) of the lower centering and fixation from rotation around the axis of each covered movable section are fixed in its lower sleeve of the type (11) and (15 ) and are interfaced with vertical posts of type (8), (10) of the adjacent female section along their inner profile with the possibility of shifting the male section in the axial direction, and elements of the type (20, 21), (22, 23) of the upper centering and locking against rotation around the axis of each covered slide the bottom sections of type (6), (7) are mounted in the upper sleeve of type (9), (15) of the adjacent female section of the type and are coupled to vertical posts of type (10), (14) of the male section along their external profile with the possibility of shifting the male section in the axial direction. In accordance with these features, these mates can be precisely centered like a well-known splined joint, both along the side surfaces of the profiles and along the protrusions / depressions of the centering elements. At the same time, which is important, the mates can be performed with moderate interference, which will contribute to the complete exclusion of radial backlash sections TM. The specified interference will not lead to a dull jamming of the movable sections, as would inevitably happen in a tubular mast, because resilient vertical posts, unlike pipe walls, are flexible in the radial direction.

3. The decrease in the radial dimensions of the TM is achieved due to the fact that the elements of locks of type (18) of mutual axial fixation of adjacent sections, which are mounted in the upper bushings of type (12), (16) of the movable sections, can be radially displaced inside the covered section, in the free the space between the vertical racks of adjacent sections, which is not feasible in the tubular sections of analogues and prototype.

4. An increase in the reliability of TM is achieved, firstly, by increasing the number of elements of the lower type (13), (17) and the upper type (20, 21), (22, 23) of centering and fixation from rotation around the axis of each covered movable section . According to the essence of the utility model, their number is at least four for each movable section, two from the bottom and top, because the number of these elements, both upper and lower, corresponds to the number of vertical posts of type (10), (14). Secondly, an increase in the indicated reliability is achieved by the fact that, according to the essence of the utility model, the interface area of even a single centering and fixing element, for example, a protrusion (13), since its radial size is not limited by the slot annular space, significantly exceeds the area of the key with a groove when these elements are located in narrow annulus of the sections, as is the case in the prototype.

The utility model meets the criterion of industrial applicability, since currently all the technologies and components necessary for its production exist.

Claims (23)

1. Telescopic mast, containing the base and mounted on the base of the drive with a vertical lead screw, on which a groove for accommodating nuts is made, containing two limit switches, and also containing at least three axial screws, telescopically embedded in one section, the outer section is stationary fixed at the base, and the remaining sections are installed with the possibility of mutual movement - telescoping along their common central axis, with each movable section equipped with elements of the lower and upper centering and fixing it against rotation around the axis, on the upper part of each section there are installed elements of locks for mutual axial fixation of adjacent sections with the possibility of operation of these locks in extreme positions of telescoping sections, and the lower part of each movable section is equipped with an axial screw and an axial-absorbed nut, characterized in that - the stationary section is formed by profiled vertical struts with a rectilinear lateral generatrix, located axisymmetrically, in an amount of at least two, reinforced with its lower part at the base, and the upper part in the upper sleeve of this section; - each movable section is formed by profiled vertical struts with a rectilinear lateral generatrix, located axisymmetrically, in an amount of at least two, reinforced with its lower part in the lower sleeve of this section, and the upper part in the upper sleeve of this section; - adjacent sections with arrays of their racks are mutually deployed around the axis; - the elements of the lower centering and fixation from rotation around the axis of each male movable section are mounted on the lower sleeve and mated to the vertical posts of the adjacent female section along their inner profile with the possibility of shifting the male section in the axial direction; - the elements of the upper centering and locking against rotation around the axis of each male movable section are mounted on the upper sleeve of the adjacent female section and mated with the vertical struts of the male section along their external profile with the possibility of shifting the male section in the axial direction. 2. The telescopic mast according to claim 1, characterized in that the profiled vertical posts are made of metal. 3. The telescopic mast according to claim 1, characterized in that the profiled vertical posts are made of plastic. 4. The telescopic mast according to claim 1, characterized in that the profiled vertical posts are made of composite material. 5. The telescopic mast according to claim 1, characterized in that the profile of the uprights has a T-shaped cross section (Taurus). 6. The telescopic mast according to claim 1, characterized in that the profile of the uprights has a U-shaped cross section (channel). 7. The telescopic mast according to claim 1, characterized in that the profile of the uprights has an arched cross section (trough-shaped). 8. The telescopic mast according to claim 1, characterized in that the profile of the uprights has a polygonal cross section. 9. The telescopic mast according to claim 1, characterized in that the adjacent sections contain the same number of racks and the arrays of these racks are mutually rotated around an axis through an angle of 360 ° / 2N, where N is the number of racks in the section. 10. The telescopic mast according to claim 1, characterized in that the elements of the lower centering and fixation from rotation around the axis of each covered movable section about the axis are made in the form of protrusions on the lower sleeve of this section. 11. The telescopic mast according to claim 1, characterized in that the upper centering element of each male movable section is made in the form of a washer with slots, which is mounted on the upper sleeve of an adjacent female section and is connected with its vertical slots to the vertical struts of this male movable section along the external profile of these racks. 12. The telescopic mast according to claim 1, characterized in that the vertical racks in each section or in separate sections are interconnected by rigid jumpers. 13. The telescopic mast according to claim 12, characterized in that the rigid jumpers are made in the form of annular sectors. 14. The telescopic mast according to claim 1, characterized in that the vertical racks of each movable section are located at an acute angle in the range from 0 to 5 angular degrees with respect to the central axis of the section, with the apex of the angle pointing upward. 15. The telescopic mast according to claim 1, characterized in that the shock absorbers of the nut are made in the form of washers made of rubber or rubber-textile material. 16. The telescopic mast according to claim 1, characterized in that all the sliding surfaces of the uprights are provided with an antifriction coating. 17. The telescopic mast according to claim 1, characterized in that the elements of the lower centering and fixing of each covered movable section from its rotation around the axis, as well as the elements of its upper centering and fixing from its rotation around the axis are made of antifriction material or provided with an antifriction coating. 18. The telescopic mast according to claim 1, characterized in that the mast sections are provided with separate corrugated protective elements or common corrugated protective elements made of elastic material.

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