FR2729494A1 - Acoustic insulation for pneumatic tool - Google Patents

Abstract

The insulation for suppressing noise from a tool or machine (44) operating on or generating compressed air, consists of flexible tubular chambers (10) which can be inflated by the compressed air, and placed over at least one noise-generating section of the tool or machine. The chambers can be in layers and have a noise-absorbing material between them, e.g. of cardboard pulp, rock wool, a non-woven fabric, or a combination of these. They can be fixed to the ground by weights or anchors, and formed in a ring or tunnel-shape.

Description

 The present invention relates to an acoustic insulation structure intended, in particular, to dampen the noise generated by a tool operating with compressed air and generating compressed air.

 It is known that compressed air tools, such as a jackhammer, which are often impact tools, and the associated compressors generate very high noise levels and are very annoying for the vicinity of the site, especially in urban areas.

 Composite structures have thus been developed intended to cover the internal face of the compartments in which there are particularly noisy compressors or diesel engines, as, for example, described in document FR-A-2 640 068. Document FR-A- 2,562,699 describes another complex wall covering absorbing acoustic waves. However, if such structures can be used indoors, they are completely unrealistic for isolating a site outside.

 Tools of the jackhammer type have also been developed, the movable elements of which are provided with elastic means to dampen noise. Document FR-A-2 540 418 describes such a tool. Document DE-A-4 239 665 proposes another structural solution. Reducing the noise level of compressors has also been envisaged, for example, among many others, in FR-A2 638 485, in FR-A-2 484 560 and in US-A-4 982 812, by structural modifications. , a local production of foam or the implementation of vacuum chambers.

 Document JP-A-59/054893 describes a rigid structure completely surrounding the compressor and using two walls between which an air layer ensures the damping of noise.

This is an irremovable structure that cannot be used on an outdoor site.

 More practical, document DE-A-3 833 053 relates to the use of air cushions under the machine, so as not to transmit vibrations through the ground. The machine's own weight ensures the pressure required in the cushions.

 The object of the present invention is to avoid the transmission of noise by ambient air, and to be usable in particular on outdoor construction sites in an urban environment.

 The present invention also aims at an economical and removable device intended to quickly and effectively provide acoustic insulation of such sites.

 The present invention also aims at a structure which can be folded and occupies only a limited space when it is not used.

 All of these aims are achieved with an acoustic insulation structure, in particular for damping the noise generated by at least one tool operating with compressed air and / or generating compressed air, constituted by a plurality of adjacent flexible tubes inflatable by means air from this tool, and arranged opposite at least one noisy part of the tool.

 Preferably, each of the tubes has an at least partially cylindrical shape in section and the structure comprises several layers of tubes.

 Advantageously, a material forming a noise trap can be interposed in the space left free between the tubes, for example, a chewed cardboard, rock wool, a nonwoven fabric, or combinations thereof.

 After inflation of the structure, the surplus compressed air can be favorably used to ventilate the isolated part by means of at least one leak with controlled air flow or a pressure threshold valve.

The invention will be better understood, and other objects, advantages and characteristics thereof will appear more clearly on reading the following description of preferred embodiments given without limitation and to which a plate of drawings is attached. on which
Figures 1 A and 1 B show in section two embodiments of a structure according to the invention
Figure 2 illustrates an embodiment intended to isolate a noise generating part of a jackhammer
Figure 3 schematically illustrates a structure according to the invention intended for use on a vertical site; and
Figure 4 schematically illustrates a structure according to the invention intended for a horizontal site in an urban environment.

 Referring now to the Figures, there is shown diagrammatically Figures 1 A and 1 B, in section, two embodiments of an acoustic insulation structure according to the invention, when it is inflated. This linear structure consists of a plurality of flexible tubes 10. These tubes 10 preferably have a cylindrical shape in section. However, one can consider strands of partially cylindrical shape in section or, even, of polygonal shape. The cylindrical shape has the advantage of being the least expensive, because the simplest to produce.

 Figure 1 A, the structure comprises a plurality of strands 10 arranged in parallel rows and glued together at perpendicular radii, while, in Figure 1 B, the strands 10 are staggered.

 The strands 10 are bonded together by any conventional means, for example, by heat bonding, high frequency welding or by polymerization, so as to adapt to the dimensions of the site thus protected and of the area to be acoustically isolated.

 According to a preferred embodiment, the structure comprises several layers of tubes, so as to ensure better noise damping. Between these tubes, it is advantageous to have a material forming a noise trap 12, for example of the cardboard chewed type, rock wool, non-woven fabric or equivalent, or combinations of these. Obviously, this material forming a noise trap 12 will be essentially placed facing the source of noise.

 In a preferred embodiment, the tubes have a diameter of between 10 and 50 centimeters approximately depending on the applications and the number of layers provided, and are made of a flexible plastic material. When this flexible plastic material has a non-smooth exterior surface, noise absorption is much better.

 This plastic material can be transparent or opaque.

Preferably, it will be provided to receive advertising spaces externally or to be coated with a filtering layer making it possible to protect from external radiation the people working under the structure.

 Those skilled in the art will have understood that the structure according to the invention will have a minimum volume and that it will be completely foldable when it is not inflated, and that it will be self-supporting and rigid when it is inflated. However, anchoring and / or ballasting (not shown in the Figures) will be (will) be provided when the structure is inflated, so as to prevent it from being taken in the wind.

 Advantageously, it is the tool which it insulates phonically which will ensure its inflation and its maintenance. This tool is, at least, either a tool - such as a jackhammer - operating with compressed air to ensure percussion, or a compressor generating compressed air. This structure can, of course, isolate a set of tools of this type or other types, and even only protect a site against prying eyes or protect workers from external nuisances.

 Due to the pressures generated by the compressors, pressures which can rise up to approximately 10 bars, it may be favorable - but not essential - to have a pressure reducer between the compressor and the compressed air supply ducts of the flanges of the structure according to the invention. In fact, the pressure necessary to stiffen the structure is around 0.1 to 0.2 Bar approximately.

The surplus of compressed air applied to the strands of the structure can then be favorably used to ventilate the part isolated by the structure. For this purpose, leaks with controlled or uncontrolled air flow, or pressure threshold valves can be provided opposite the insulated part in order to provide a large air current under the structure.

 Furthermore, as soon as the tubes are continuously supplied with compressed air, even when they are inflated, untimely small perforations in the tubes are then without major effect on the expected acoustic function of the structure.

 In Figures 2 to 4, there is shown schematically several embodiments of the invention.

 Figure 1, the structure is very small and is intended to dampen the noise generated by a jackhammer whose handle 20 is seen enclosing the air motor and the peak 22. The peak 22 is enclosed in a skirt 24 formed by a plurality of adjacent toroidal tubes glued to each other. The tubes are inflated by means of the compressed air necessary for the jackhammer. The upper part of the skirt 24 is fixed to the handle 20 of the jackhammer, while the last lower tube is supported on the ground 26, so as to isolate the space. The noises generated in this space are thus trapped by this skirt-like structure where they are clearly damped. Although the shock wave propagating on the ground 26 itself is not thus damped, it results from the use of this structure a significant reduction in the noise nuisance in urban areas.

 Figure 3 shows schematically the vertical wall of a wall 30, for example in facelift. A scaffold 32 is provided to allow the work to be carried out. The vertical site is protected by a structure 34 according to the invention. This structure consists of a plurality of tubes substantially affecting the shape of a half-tunnel whose soniiet 36 rests on the wall 30. This structure is favorably anchored to the scaffolding. The structure 34 then has several functions, since, not only does it dampen the noise generated by the use of the cleaning means, but also it protects the personnel against the bad weather and conceals the site. In addition, the exterior vertical face of the structure can favorably determine advertising spaces.

 Figure 4, the site is horizontal and requires, for example, the construction of a trench 40 in a sidewalk 42. A compressor 44 is provided to supply jackhammers or the like with compressed air. The structure used 46 then favorably takes the form of a tunnel the legs of which rest on the sidewalk 42 on either side of the trench 40, a ballast being provided to keep the tunnel in place even in strong winds. Part of the compressed air is diverted to the structure by an inlet duct 48, while an overpressure in the structure is avoided by means, for example, of air leaks with controlled flow or with threshold valves (not Again, the structure 46 has several functions: noise protection for the neighborhood, weather protection for the workforce, with, if necessary, a kind of air conditioning or internal ventilation determined by a current of permanent air created by excess compressed air.

 The tubes can be made of different plastic materials, for example 0.25 mm thick PVC to be transparent, polyester fabrics comprising PVC to be opaque. They will then be glued to each other by the known technique of high frequency welding. They can also be produced by means of a rubberized canvas, with a bonding produced by polymerization.

 Those skilled in the art will have understood that such structures can be manufactured to the dimensions that the user desires, and are very compact when they are not inflated.

In addition, a local tear or drilling of a rod does not substantially affect the rigidity of the structure, since it is permanently supplied with the compressed air necessary on the site from which it takes only a very small part . A regulator is thus often necessary between the compressed air generator and the air intake of the structure.

 In addition, these structures provide a certain level of comfort for the staff and greatly contribute to the reduction of noise pollution for the urban neighborhood.

 Such a structure in accordance with the invention also finds application in the rapid, efficient and inexpensive production of noise barriers. In this case, it will include a small compressed air generator intended for its sole use, therefore very little noise itself, due to the low overpressure required to ensure the rigidity of the structure. In addition, this small generator can favorably be controlled directly depending on the level of pressure prevailing in the tubes. Such an anti-noise wall finds its application in a noisy industrial environment, in particular in sheet metal workshops.

 Although we have represented and described what are currently considered to be the preferred embodiments of the present invention, it is obvious that those skilled in the art will be able to make various changes and modifications thereto without departing from the scope of the present invention as defined below.

Claims (12)

 1- Acoustic insulation structure, in particular for damping the noise generated by at least one tool (20, 22, 44) operating with compressed air and / or generating compressed air, characterized in that it is constituted by a plurality of adjacent flexible tubes (10) inflatable by means of the air of said tool (20, 22, 44), disposed facing at least one noisy part (22) of said tool.  2 - acoustic insulation structure according to claim 1 characterized in that each of said tubes (10) has an at least partially cylindrical shape in section.  3 - acoustic insulation structure according to claim 1 or 2 characterized in that said plurality of tubes (10) comprises several layers of tubes.  4 - acoustic insulation structure according to claim 3 characterized in that a material forming a noise trap (12) is interposed in the space left free between said strands (10).  5 - acoustic insulation structure according to claim 4 characterized in that said material forming a noise trap (12) is chosen from a chewed cardboard, rock wool, nonwoven fabric, and combinations thereof.  6 - Sound insulation structure according to any one of the preceding claims, characterized in that it is fixed to the ground by ballasting and / or anchoring.  7 - Sound insulation structure according to any one of the preceding claims, characterized in that it affects the general shape of a tunnel (46).  8 - acoustic insulation structure according to any one of claims 1 to 6 characterized in that it affects the shape of a half-tunnel (34) resting, by its upper part (36), against a .ur ( 30).  9 - acoustic insulation structure according to any one of claims 1 to 6 characterized in that the said flanges affect a substantially toroidal shape and enclose a noise generating part (22) of said tool.  10 - Acoustic insulation structure according to any one of the preceding claims, characterized in that, after its inflation, the surplus air included is used to ventilate the insulated part by means of at least one leak at a flow rate of controlled air or at least one pressure threshold valve.  11 - Sound insulation structure according to any one of the preceding claims, characterized in that the said tubes (10) are bonded to each other according to the dimensions of the area to be isolated.  12 - Sound insulation structure according to any one of the preceding claims, characterized in that the said tubes (10) are made of a flexible plastic material having a non-smooth exterior surface.