EP0067903A2 - Tubular mast constituted of stacked elements - Google Patents

Abstract

A tubular mast constituted of stacked steel tube sections, the diameter of which decreases towards the top of the mast and which have a conically tapering portion on the top end of which a circumferential shoulder is formed, upon which the stacked tube section sits. The tapering portion has a cylindrical or conical extension which adjoins the circumferential shoulder and over which the upper tube section is placed. Located between the two tube sections is a conical, bush-like clamping device, via which the frictional and clamping forces required to hold the sections together are transmitted. The tube sections constructed in this way do not need to be welded together or adhesively bonded. They can be used for the assembly of tubular masts of any desired length at the erection site, thereby saving considerable transport and storage costs which are normally incurred when the tubular masts have to be transported or stored in their full length. <IMAGE>

Description

The invention relates to a tubular mast made of stacked tubular bodies, the diameter of which decreases towards the mast tip and which have a support for the tubular body to be attached in the region of their upper ends. In a known tubular mast of this type (DE-OS 1 434 785), the tubular bodies plugged onto one another to form a tubular mast are provided at their upper ends with firmly molded or loosely inserted flanges as supports for connecting the tubular bodies arranged one above the other, the connection itself using rod-shaped or rod-shaped clamping elements,. which are passed through the tubular body and pull them together in the longitudinal direction of the tubular mast. Due to the required tensioning elements, such a tubular mast requires Their assembly during assembly of the individual tubular bodies to form the tubular mast and the bearings required for guiding and holding the tensioning elements within the tubular mast involve a considerable outlay in terms of production technology and materials.

In addition, it must be possible at the top or bottom of the assembled tubular mast to brace the tie rods after they have been inserted in order to introduce the tensile forces required for the tubular mast to hold together in the tubular body. For this, however, additional mounting openings in the head-side or bottom-side tubular body are necessary. In addition, the manufacturing and material expenditure increases in those cases in which the flanges serving as supports for the adjacent tubular bodies are not integrally formed on the tubular bodies but are loosely inserted into them. Even when using molded flanges, machining is unavoidable in order to create a suitable fit for the attached tubular body. Finally, it is obviously not possible to do without welding of the individual tubular bodies in spite of their bracing with the aid of the rod-shaped or rod-shaped elements in such tubular masts if the tubular masts are to be relatively long. Such welding of the individual tubular bodies in the area of their supports, however, represents a substantial additional effort which can increase the manufacturing costs even further.

The object of the invention is therefore to design the tubular mast of the type mentioned in such a way that the individual tubular bodies do not have to be clamped to one another or welded and still masts of any length can be produced without the risk that the individual stacked tube Detach body from each other or the strength of the mast, in particular its bending strength, is exceeded under the forces acting on it during and after the mast installation, as a result of which the mast breaks or kinks.

This object is achieved in that the tubular body is steel pipe sections, each having a retracted section that forms a circumferential shoulder against which the attached pipe section is directed and whose depth A measured in the direction of the longitudinal axis of the weft is greater than the wall thickness B of the pipe section attached , wherein the retracted section has a cylindrical or conical, tubular continuation adjoining the circumferential shoulder, via which the friction and clamping forces required to hold the pipe sections together can be transmitted by means of a conical, bush-like clamping device to the inside of the wall of the pipe section attached.

This construction makes it possible to manufacture pipe masts of any diameter and length by stacking steel pipe sections without them being welded or glued. With the help of the conical, socket-like clamping device, the superimposed shots are held in a rotationally fixed manner, but on the other hand are not so firmly connected that they cannot be detached from one another again, for example when the mast height has to be changed after the masts have been set up, if the masts are used as lighting masts serve and for example new types of luminaires or other fittings with appropriate mirror optics should be used.

Furthermore, the tubular masts according to the invention enable a considerable reduction in transport and storage costs, since the masts in lengths of more than 4 m required special transport vehicles. Now all usual means of transport can be used, since the mast sections do not exceed a maximum length of 4 m and are only put together at the installation site of the tubular mast.

According to an advantageous embodiment of the invention, in the case of a cylindrical continuation, the socket-like clamping device consists of a first cylindrical socket with an external cross-section which enlarges conically towards the circumferential shoulder and a second cylindrical socket which is inserted over the first socket and conically enlarges towards the circumferential shoulder Internal cross section formed. In this case, the first bushing can have at its upper end an annular flange which is directed inwards to the longitudinal axis of the weft and which sits on the end face of the cylindrical extension.

In this context, it has proven to be particularly advantageous for the second bushing to provide it at its lower end with an outwardly directed ring flange which sits on the lower end face of the plug-in pipe section which contains the second bushing. This ring flange is designed in the manner of a sealing ring seated on the circumferential shoulder, as a result of which a special seal can be omitted.

In the cases in which the tubular continuation adjoining the circumferential shoulder is not cylindrical, but conical, the bush-like clamping device can consist of a single cylindrical bush with an inner diameter that increases continuously towards the circumferential shoulder. On this saves one of the two bushings without losing the advantageous properties of the construction according to the invention.

In order to adapt to manufacturing tolerances, which inevitably occur in the manufacture of the bushings, if this manufacture is to be carried out at a reasonable cost, it has also proven to be advantageous to provide the walls of the bushings with a slot which extends in the direction of their longitudinal axis.

According to a further advantageous embodiment of the invention, the circumferential shoulder can lie at the end of the conically drawn-in section and form the transition to the cylindrical section onto which the cylindrical section of the following pipe section can be plugged. In order to give the pipe mast a smooth outer surface in the connection area of the stacked pipe sections, it has proven to be advantageous to have the surfaces of these pipe sections merge flush in the area of the circumferential shoulder, i.e. without forming a shoulder or a step.

In order to further reduce the manufacturing costs of the pipe mast, by avoiding flanging of the pipe section to be attached and the production and application of a special seal, which is located on the circumferential shoulder of the lower pipe section, and, moreover, not inconsiderable material stresses that occur during the formation of the horizontal circumferential shoulder and can lead to cracking, a further embodiment of the invention has proven particularly useful. In this embodiment, the clamping bush is on its lower, the peripheral shoulder of the lower pipe section facing end with an annular flange which has an upward shoulder with which it sits on the end face of the attached pipe section and has a small distance from the circumferential shoulder of the lower pipe section.

This not only achieves a perfect fixation of the clamping bush in the pipe to be attached, but also gives the possibility to design the ring flange itself as a spacer or sealing ring seated on the circumferential shoulder, which means that a special, separate spacer or sealing ring can be omitted.

The ring flange can form a downward-facing bearing shoulder, which rests on the circumferential shoulder of the lower pipe section, wherein, according to a further advantageous embodiment, the circumferential shoulder forms a conical pipe section, the inclination angle a. to the pipe longitudinal axis is greater than the angle of inclination β of the conically drawn-in section of the lower pipe section adjoining the circumferential shoulder.

In this context, it has also proven to be advantageous to divide the clamping bush into two parts by means of two axially running slots and then to have them pressed against the inner wall of the upper pipe section to be attached by a spring which is arranged in an annular groove in the two clamping bush parts . In this way, the clamping bush inserted into the upper pipe section is clamped there, so it cannot slip out when the upper pipe section is plugged onto the lower one, which makes installation considerably easier.

Instead of two axially extending slots, the clamping bush can also be provided with only a single axial slot which can be compressed when it is pushed into the upper pipe section and thereby clamps the inserted clamping bush in the pipe section.

• Fig. 1 eine Längsschnittansicht eines Teils eines erfindungsgemäßen Rohrmastes im Bereich zweier aufeinandergesteckter Stahlrohrschüsse, wobei sich die Umfangsschulter am Ende des konisch eingezogenen, unteren Rohrschusses befindet,
• Fig. 2 eine Schnittansicht des Rohrmastes von Fig. 1 längs der Linie 2-2 in Fig. 1,
• Fig. 3 eine mit Fig. 1 vergleichbare Ansicht eines Teils des erfindungsgemäßen Rohrmastes, wobei jedoch der aufgesteckte Stahlrohrschuß in strichpunktierter Darstellung erscheint, die sich an die Umfangsschulter anschließende Fortsetzung sich nach oben zu konisch verjüngt und zwischen ihr und dem aufgesteckten Schuß eine einteilige Klemmbuchse angeordnet ist,
• Fig. 4 eine mit Fig. 3 vergleichbare Ansicht eines Teils des erfindungsgemäßen Rohrmastes, bei der jedoch die Klemmbuchse an ihrem unteren Ende mit einem Ringflansch versehen ist, der von der zur Rohrlängsachse geneigt verlaufenden Umfangsschulter des unteren Rohrmastes einen geringen Abstand aufweist,
• Fig. 5 eine der Fig. 4 ähnliche Längsschnittansicht, bei der die Klemmbuchse zweigeteilt und durch eine Feder an den oberen Rohrschuß angepaßt ist, und
• Fig. 6 eine Querschnittsansicht des Rohrmastes längs der Linie 3-3 in Fig. 5.

The invention is explained in more detail below with reference to the exemplary embodiments shown in the drawing. The drawing shows:

• 1 is a longitudinal sectional view of part of a pipe mast according to the invention in the area of two steel pipe sections which are plugged onto one another, the circumferential shoulder being located at the end of the conically drawn-in lower pipe section,
• 2 is a sectional view of the tubular mast of FIG. 1 along the line 2-2 in Fig. 1,
• Fig. 3 is a view comparable to Fig. 1 of a part of the pipe mast according to the invention, but the attached steel pipe section appears in dash-dotted lines, the continuation following the circumferential shoulder tapers upwards to a cone and a one-piece clamping bush is arranged between it and the attached section is
• 4 is a view comparable to FIG. 3 of a part of the tubular mast according to the invention, but in which the clamping bush is provided at its lower end with an annular flange which is at a small distance from the circumferential shoulder of the lower tubular mast which is inclined to the longitudinal axis of the tube,
• Fig. 5 is a similar to FIG. 4 longitudinal sectional view, in which the clamping bush is divided in two and is adapted by a spring to the upper pipe section, and
• 6 is a cross-sectional view of the pipe mast taken along line 3-3 in FIG. 5th

1 shows two stacked steel pipe sections 2, 3, of which the lower pipe section 3 has a conically retracted section 17 which begins at a lower cylindrical mast section 22 shown in FIG. 3 and tapers to the circumferential shoulder 4, which forms the transition to the cylindrical section 19 onto which the cylindrical section 21 of the following upper steel tube section 2 is attached.

In this embodiment, the circumferential shoulder forms an almost horizontal support on which there is a spacer or sealing ring 6 which is flush with the outer edge of the circumferential shoulder. The depth A of the circumferential shoulder 4 measured in the direction of the longitudinal axis 18 of the weft is greater than the wall thickness B of the pipe weft 2 attached.

To hold the pipe sections together, in particular against twisting, is used a conical, bush-like clamping device which, in the embodiment shown in FIG. 1, consists of a first cylindrical bushing 7 with a cross-section which widens conically in the direction of the circumferential shoulder 4 or a continuously increasing outside diameter and from one of the above first socket 7 is inserted socket 8 with reverse taper, ie with the inner cross-section or inner diameter increasing continuously in the direction of the circumferential shoulder 4.

The socket 7 has at its upper end an inwardly directed to the longitudinal axis 18 of the ring flange 9, with which it rests on the end face of the cylindrical extension 19.

The second bushing 8 has at its lower end an outwardly directed annular flange 5, which sits on the lower end face of the attached upper pipe section 2 and, in the installed state shown in FIG. 1, rests as a spacer or sealing ring 6.

The two bushings 7 and 8 are thus wedged to one another and to the pipe sections delimiting them in the installed state of two stacked pipe sections, thus transmitting the friction and clamping forces required to hold the two pipe sections 2, 3 together. On the other hand, this cohesion is not so strong that the pipe sections cannot be separated from one another with a suitable lever tool if the pipe mast height is to be changed by using longer or shorter sections. The latter would be the case, for example, if the tubular mast is set up as a light mast and the light point height changes due to a change in the type of luminaire or the fitting with other mirror optics.

The two wedges 7, 8 which are seated one on top of the other are each provided with a slot 15, 23 which extends in the direction of their longitudinal axis, as can be seen from FIG. 2. These slots allow the cylindrical bushes with conically tapering cross-sectional dimensions to be stretched or pressed together to adapt to manufacturing tolerances when the two tubular mast sections 2, 3 are plugged onto one another. This assembly takes place in such a way that the first bushing 7 is first plugged onto the cylindrical extension 19 of the lower pipe section 3, until it stops Ring flange 9. Then the upper pipe section 2, into which the second cylindrical bushing 8 has already been inserted up to the stop of its ring flange 5, is pushed onto the bushing 7 until the ring flange 9 meets the spacer or sealing ring 6.

The length of the overlap area of the two pipe sections 2, 3 connected to one another, along which the inside of the upper, placed pipe section with the inserted second bushing 8 rests on the outside of the first bushing 7 plugged onto the lower pipe section, is greater than the average pipe section diameter in the overlap area of the two shots.

In the embodiment shown in FIG. 3, instead of the two cylindrical bushings 7, 8, a single bushing 10 is used, which has an internal cross section which increases conically in the direction of the shoulder 13 and which extends upwards from the shoulder 13 conical tapered continuation 20 is attached. The bushing 10 has a lower ring flange which replaces a spacer or sealing ring. The upper pipe section, which is shown in broken lines in FIG. 3, is pushed over the bushing 10.

The longitudinal sectional view of FIG. 4 shows two stacked steel pipe sections 30, 31, of which the lower pipe section 30 has a conically drawn-in section 32, the angle of inclination p of which to the pipe longitudinal axis 34 is smaller than the conical pipe section adjoining this section, which forms a circumferential shoulder 29 and whose angle of inclination to the tube longitudinal axis 34 is designated by α.

1 and 3, this tube mast also consists of several stacked tube sections 30, 31, the diameter of which decrease towards the mast tip and each have a retracted section which forms a circumferential shoulder of the type designated 29 against the the respectively attached pipe section is directed and the depth A measured in the direction of the pipe section longitudinal axis 34, as can be seen in FIG. 1, is greater than the wall thickness B of the attached pipe section. The drawn-in, conical section of the lower pipe section 30 has a conical, tubular extension 35 beyond the adjoining circumferential shoulder 39, the diameter of which continuously tapers towards the upper end of the lower pipe section 30. About this conical continuation 35 with the help of the inserted into the upper pipe section 31 clamping bush 38, the friction and clamping forces required to hold the pipe sections together are transmitted. For this purpose, the clamping bush 28 is also conical, with an internal cross-section which increases continuously in the direction of the circumferential shoulder 29.

4 and 5, at its lower end facing the circumferential shoulder 29 of the lower pipe section 30, an annular flange 24 has an upwardly directed shoulder 25 with which it can be attached on the front side of the Pipe section 31 sits. The ring flange 24 forms a downward-facing bearing shoulder 26, which is at a small distance from the peripheral shoulder 29 of the lower pipe section 30, which is approximately up to 3 mm, but in extreme cases also rests on the peripheral shoulder. This distance serves the purpose of slipping the conical clamping bush to allow with the pipe section 31 sitting on it when setting up the pipe mast until the clamping bush clamps on the surface of the tubular extension 35.

In the illustrated embodiment, the angle of inclination x of the circumferential shoulder 29 is 30 °, while the angle of inclination p of the conical, drawn-in section adjoining the shoulder in the direction of the lower end of the lower pipe section 30 is 15 °.

The angle of inclination of the tubular extension 35 of the lower pipe section to be tapered upwards is 1 ° and the outer diameter at the upper end of this continuation is 74 mm, while the outer diameter of the attached upper pipe section 31 is 76 mm. It is understood that these dimensions are only to be understood as examples, which are not intended to be limiting in any way.

The angle of inclination α, the circumferential shoulder 29 corresponds to the angle of inclination of the downwardly directed bearing shoulder 26 of the ring flange 24.

6, the clamping bush 28 is divided into two by two axially extending slots 36a and 36b, and the two clamping bush parts are pressed against the inner wall of the upper pipe socket 31 to be attached by a spring 27 which is located in an annular groove 33 of these two 5, this construction makes assembly considerably easier if the two pipe sections are to be plugged onto one another, since the spring 27 prevents the clamping bush 28 inserted into the upper pipe section 31 when the pipe is put on shot slides down. As can be seen, the spring 27 extends as an almost closed ring around the inner circumference of the two successive parts of the clamping bush 28 within the ring groove 33.

Instead of a two-part clamping bush, it is also possible to use a one-part bushing which has a single axial slot, the width of which is reduced when the clamping bush is inserted into the upper pipe section 31 by pressing together, which produces the desired clamping effect.

The ring flange 24 delimiting the lower end of the clamping bush 28 makes a separate sealing or spacer ring unnecessary and thereby simplifies the manufacture and assembly of the tubular mast. In addition, this construction ensures that the pipe sections 30 and 31 plugged onto one another remain firmly connected to one another.

In this construction, the upper pipe section 31 with the inserted clamping bush 28 is pushed onto the tubular extension 35, the conicity of which is the reverse of that of the clamping bush 28, until it clamps on the lower pipe section 30. This is usually the case before the bearing shoulder 26 of the annular flange 24 touches the circumferential shoulder 29, so that a gap C of a few millimeters up to approximately 3 mm width remains between the two parts, which slips down the upper pipe section or its clamping bush 28 ensures.

Claims (12)

1. Pipe mast made of stacked tubular bodies, the diameter of which decreases towards the mast tip and which have a support for the tubular bodies to be attached in the area of their upper ends, since - characterized in that the tubular bodies are steel tubular sections (2,3,22,30,31) , each of which has a retracted section (14, 17, 32) which forms a circumferential shoulder (4, 13, 29) against which the attached pipe section (2, 31) is directed and in the direction of the longitudinal axis (18, 34) measured depth (A) is greater than the wall thickness (B) of the pipe section (2, 31) placed on it, the drawn-in section being a cylindrical or conical, tubular extension (19, 20, 14) adjoining the circumferential shoulder (4, 13, 29) 35), via which the friction and clamping forces required to hold the pipe sections together can be transmitted to the inside of the wall of the attached pipe section (2,31) by means of a conical, bush-like clamping device (7,8; 10,28). 2. Pylon mast according to claim 1, characterized in that in the case of a cylindrical extension (19), the bush-like clamping device from a first cylindrical bush (7) with conically enlarging outer cross-section in the direction of the circumferential shoulder (4) and a second cylindrical, over the first socket inserted socket (8) with conically enlarging inner cross-section in the direction of the circumferential shoulder (4). 3. Pole mast according to claim 1 or 2, characterized in that the first bushing (7) has at its upper end an inward to the longitudinal axis (18) directed ring flange (9) which sits on the end face of the cylindrical extension (19). 4. Pylon mast according to one of claims 1 to 3, characterized in that the second bushing (8) has at its lower end an outwardly directed annular flange (5) which sits on the lower end face of the pipe section (2) to be attached, which the contains the second socket. 5. tubular mast according to claim 4, characterized in that the ring flange (5) on a on the circumferential shoulder (4) arranged spacer or sealing ring (6), and that the outer diameter of the ring flange (5) and the outer diameter of the sealing ring (6 ) correspond to the outer diameter of the circumferential shoulder (4). 6. Pylon mast according to claim 1, characterized in that with a conical continuation (20,35), the bush-like clamping device consists of a single cylindrical bush (10,28) with conically increasing internal cross-section in the direction of the circumferential shoulder (13,29). 7. tubular mast according to one of claims 1-6, characterized in that the wall of the bushings (7,8,10) has a slot (15) extending in the direction of its longitudinal axis. 8. tubular mast according to claim 6, characterized in that the clamping bush (28) at its lower end facing the circumferential shoulder (29) of the lower pipe section (30) is provided with an annular flange (24) which has an upwardly directed shoulder (25) with which it sits on the end face of the attached pipe section (31) and has a small distance from the circumferential shoulder (29). 9. Pylon mast according to claim 8, characterized in that the annular flange (24) forms a downward bearing shoulder (26) which is separated from the peripheral shoulder (29) of the lower pipe section (30) up to about 3 mm. 10. Pole mast according to claim 8 or 9, characterized in that the circumferential shoulder (29) forms a conical tube section, the angle of inclination CL to the longitudinal axis (34) is greater than the angle of inclination β of the conical necked portion (32) adjoining the circumferential shoulder. the lower pipe shot. 11. Pylon mast according to one of claims 8 to 10, characterized in that the clamping bush (28) by two axially extending slots (36a, 36b) is divided in two, and that the two parts of the clamping bush on the inner wall of the upper pipe section (31) to be plugged through a spring (27) can be pressed on, which is arranged in an annular groove (33) of the two clamping bush parts. 12. Pipe mast according to one of claims 1 to 11, characterized in that the surfaces of the stacked pipe sections (2,3; 30,31) in the region of the circumferential shoulder (4,29) merge into one another.

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