DE2806757A1 - Dynamic oscillation modulator for chimney or pylon - has resiliently applied auxiliary mass combined with resilient damping elements - Google Patents

Abstract

The damper is for steel chimneys, antenna masts, pylons, columns, cables or pipe ducts, or other components susceptible to externally generated oscillation and with inadequate inherent modulation. The dynamic oscillation damper comprises an auxiliary mass for resilient application. This mass (4) is connected with mechanical combined spring and modulation elements (5). These may be helical wire springs, with rubber or plastics inlaid in them and/or sheathing them and can be of tubular cross-section with radial loading.

Description

Dynamic vibration damper for

Attachment to Structures The invention relates to dynamic Vibration damper for attachment to structures or components, consisting of a Additional mass to be applied resiliently to the structure or component with damped oscillation. The invention also relates to vibration dampers of this type Structures or components.

It is known, structures or components, which by external excitation tend to oscillate at the basic frequency or a higher natural frequency do not have sufficient internal attenuation, especially steel chimneys, antenna supports, Pylons, supports, ropes and pipelines are provided by dynamic vibration dampers To preserve damage The excitation can be ZQB at the mentioned structures. through the Wind or seismic origin. An overview above Find the state of the art in this area with further references in essays by chor. Pítersen and G. Hirsch in "Haus der Technik - lecture publication 347 ", pages 93 to 112. In addition, DE-GM 66 09 958, DR-OS 25 51 471 and DE-OS 26 16 899 referenced.

After the calculation of dynamic vibration dampers basically is known, it comes to further development in this particular field on finding syr, -leme and structures for such vibration dampers, which are weatherproof and wear-resistant, a controllable design and increase the electrical resistance of the structure in the wind as little as possible. The known vibration dampers are not yet satisfactory in this regard. In most cases they require a relatively bulky housing and even dinn are not yet maintenance-free. In many cases, the structural design is proportionate complicated and correspondingly expensive. In other cases the masses are Vibration damper overall relatively large. With the present invention all of these disadvantages are fundamentally eliminated, and this becomes a dynamic one Vibration damper proposed in which, according to the invention, the additional mass with mechanical, combined spring-damper elements is connected.

In the case of the invention, the usual pendulum suspension of the additional mass can be used be waived, in which below the additional mass for safety reasons a fall arrester should also be attached. Compared to known Constructions with telescopic dampers results from the invention in each case a much smaller version.

In addition, the susceptibility to failure and the need for maintenance of the Telescopic dampers are avoided.

Suitable spring-damper elements are available as wire rope coil springs available that were previously under the 1-drawing GTW vibration and shock reducers especially in mechanical engineering to prevent the transmission of vibrations and shocks Applicants (llmg have found.

In a preferred embodiment of the invention, the spring and damping properties of wire rope coil springs by incorporating damping materials such as e.g. rubber or plastic, and / or coating or encapsulation with such materials set.

As an alternative to the wire rope coil springs, the spring damper elements also have a tubular, radially loaded cross-section and, if necessary, reinforced, resilient and at the same time damping material, e.g.

Consist of rubber or plastic. He prefers a modified version Steel braided hoses are also available in Frige, with the spring and damping properties as well by embedding damping materials and / or sheathing or potting with such materials are set.

It prepared proportionally with the well-known dynamic vibration dampers great difficulty, not just the vibrations in the fundamental frequency, but also to dampen tlie vibrations in higher natural frequencies, as there are several independent vibration dampers were needed. In a preferred embodiment the invention is now proposed that both to dampen vibrations in the basic frequency as well as in higher natural frequencies two or more spring-damper elements such with mutual play in the direction of the spring travel side by side or in one another are arranged so that they can be loaded one after the other with increasing oscillation amplitude are.

Alternatively, in principle integrated spring-damper elements could be used with a non-linear spring characteristic can be used.

In each case one gains the advantage that several natural frequencies by means of a single additional mass and an extremely compact vibration damper system can be dampened.

The structure or component with a vibration damper according to the invention is designed in a first practically preferred embodiment so that the weight the additional mass is supported exclusively on the spring damper elements. In another practically feasible embodiment of the invention that is at rest Weight of the additional mass on supports articulated below. In the verauch for the oscillating suspension of the additional mass hl ', this construction has the advantage that the TrRgring for the supports and the additional msase is below the same and thus secures against falling. Another advantage is that the Additional mass can be arranged directly at the very end of the structure. Besides However, as before, a pendulum suspension of the additional mass is also possible Use of the proposed spring-damper elements between the structure and the Additional mass. The spring-damper elements can also be placed indirectly between the additional mass and the structure are switched on, for example, on the one bearing the additional mass Attack the pendulum or linkage.

The invention is illustrated below with reference to in the drawing Embodiments explained in more detail. They show: FIG. 1 a vertical section by a dynamic vibration damper attached to the outside of a steel chimney according to the invention, Fig. 2 is a plan view of the vibration damper according to Fig. 1, 3 shows a vertical section through one in a steel chimney installed vibration damper according to the invention, Fig. 4 is a plan view of a Spring-damper element with non-linear spring characteristics.

The exemplary embodiments of the invention shown in the drawing Dynamic vibration dampers can, as the comparison of Fig. 1 and 3 shows, inside or cracks on a structure, e.g. a steel chimney 1.

It is not necessary that the Kittellängsach; e of to damping structure or component is vertical, because the invention is practical regardless of the location of the parts and the type of excitation.

Two brackets 2 diametrically opposite one another are fixed on the steel chimney 1 attached, on which on articulated pendulum supports 3 the weight of a Additional mass 4 rests, which e.g. has the shape of a closed or open round or polygonal ring. Alternatively, it can also be distributed over the circumference Find single dimensions application. In practice, the additional mass is of the order of magnitude 1 to 2% of the total mass of the structure to be damped.

There are combined spring-damper elements between the additional mass 4 and the chimney 1 5 used, which in a practical embodiment wire rope coil springs that are loaded across their center line. The connection between the spring-damper elements and the additional mass 4 on the one hand and the chimney on the other hand can be done via terminal strips on the wire rope coil springs, as is the case with such Spring elements is known.

Wire rope coil springs have a damping effect due to the Friction of the wires against each other. They are resistant to corrosion and maintenance-free, take up little space and have a large load-bearing capacity. Because of the latter property, the consoles 2 and pendulum supports 3 are omitted. For better adjustment of the damping properties the spring-damper elements can, as mentioned above, g; made of the same materials or applied.

In contrast to most other known dynamic vibration dampers In the case of the invention, there is no need for stop buffers for soft catching extreme Amplitudes of the oscillating additional mass 4.

The wire rope coil springs selected as an example can be set according to 4 into one another, in which case a wire rope coil spring 6 of larger diameter a designated 7 receives smaller. To the connection?: No of the larger wire rope coil spring 6 with the K "tn 1 and with the additional mass 4 serve two diametrically opposite terminal strips 8 and 9, the terminal strip 8 also holds the wire rope coil spring 7. The interpretation will be made that the outer wire cable coil spring 6 to dampen the vibrations of the chimney in the basic frequency is sufficient. If the chimney closes in a higher natural frequency begins to oscillate, which is insufficient due to the outer wire rope screw spring 6 is damped, the inner wire rope coil spring 7 also comes into action, which is sized to work with the outer wire rope coil spring 6 and the additional mass 4 a dynamic vibration damper for the higher natural frequency forms.

It goes without saying that the invention also applies to other suitable ones Spring-damper elements made of materials or combinations other than those mentioned of materials, provided that they extend in the same way as claimed, let arrange. There are also numerous variations of the shape and Support structures the additional mass possible. A modification compared to the embodiment described It also means that the spring-damper elements in constructions according to Fig. 1 or 3 not necessarily fixed both to the structure and to the additional mass must be connected, because it is sufficient to achieve the desired function one one-sided fastening.

Claims (11)

Claims Dynamic vibration damper for attachment to Structures or components, consisting of a resilient structure or component to be attached Additional mass with damped oscillation, d u r c h e ic e fl fl -z e i c h n e t that the additional mass (4) with mechanical, combined spring-1) damper elements (5) is connected. 2. Vibration damper according to claim 1, d a d u r c h g e k e n n z e i c h n et that the spring-damper elements (5) are wire rope coil springs. 3. Vibration damper according to claim 2, d a d u r c h g e k e n n z e i c h n e t that the spring tud damping properties of the wire rope coil springs (5) by storing damping materials such as rubber or plastic, and / or coating or potting with such materials are set, 4. Vibration damper according to claim 1, that the spring-damper elements (5) have a tubular, radially loaded cross-section and optionally a reinforced, resilient and at the same time damping material, such as rubber or plastic. 5. Vibration damper according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the spring-damper elements (5) consist of steel mesh hoses, whereby the spring and damping properties are achieved through the incorporation of damping materials and / or coating or potting are set with such materials. 6. Vibration damper according to one of the preceding claims, d a d u r c h e k e n n n z e i c h n e dfl for damping vibrations both in the fundamental frequency as well as two or more spring-damper elements in a higher natural frequency (6, 7) side by side or in one another with mutual play in the direction of the spring travel are arranged so that they can be loaded one after the other with increasing oscillation amplitude are. 7. Vibration damper according to one of claims 1 to 5, d u u r c h e k e n n n n z e i n e t, for damping vibrations both in the fundamental frequency as well as in higher natural frequencies integrated spring-damper elements with non-linear Spring constants are provided. 8. Structure or component with a vibration damper nteh one of the Claims 1 to 7, d a d u r c h g e -k e n n n z e i c h n e t that the weight the additional fair (4) is supported exclusively on the spring-damper elements (5) is. 9. Structure or component with a vibration damper or one of the Claims 1 to 7, d a d u r c h g e -k e n n n z e i c h n e t that the weight the additional mass (4) rests on supports (3) articulated underneath. 10. Building or component according to claim 8 or 9, d a -d u r c h g e k e n n n z e i c h n e t that the spring-damper elements (5) axially at the level of the Additional mass (4) are arranged. 11. Building or component according to claim 8 or 9, d a -d u r c h g e k e n n n n e i c h n e t that de spring-damper elements (5) between the additional mass (4) supporting columns (3) or pendulums and the structure (1) are clamped.