DE202015004064U1 - Device for reducing sound pressure levels - Google Patents

Abstract

A sound absorbing device comprising a spaced, planar absorption element for attachment, integration or combination to or with a flow-tight surface, which may be formed as a support or construction layer and an intermediate cavity, free of fiber, foam and dams or other fillers is characterized in that the spaced sound absorbing member has a porous structure which is bound from a mixture of natural and / or artificial aggregates and an organic or inorganic binder and the necessary for the setting of the binder water or hardeners and additives and / or additives ,

Description

The invention relates to a device and a method for reducing the sound pressure level of construction elements and / or parts thereof.

The steadily rising energy demand can often not be met in rapidly growing regions. Therefore, the use of suitable decentralized facilities is inevitable, especially in rural areas seems inevitable. These include biogas plants that are used in farms and wastewater treatment plants for energy production and waste disposal. In combined heat and power plants (CHP) of the biogas plant, heat and electricity are simultaneously generated by combined heat and power (CHP). The heat generated in this case is decoupled by the so-called heat exchanger and can then be used for heating. A heat exchanger, also called a heat exchanger, is a machine that transfers heat or thermal energy from one material stream to another. The engines for a CHP are gas engines that have been specially developed for gas operation. Biogas can be used to operate these engines, so the biogas can be used to generate heat and electricity. Combined heat and power plants are particularly economical in places where heat and electricity are needed at the same time. The surplus heat can be fed into district or local heating networks and the surplus electricity into the public grid. In addition to biogas, the plants can also be operated with natural gas, LPG, diesel or rapeseed oil.

The problem with the operation of combined heat and power plants, the resulting noise emissions combustion engines of up to 120 dB (A). Since CHPs are also built close to residential buildings, problems can occur due to noise pollution (sound immissions in living spaces), especially low-frequency airborne noise. Low-frequency sound is sound with frequencies below 100 Hz. Measurements at an immission location at a distance of approx. 40 m from a CHP indicate the existence of such frequencies.

Noise is one of the environmental pressures that directly affect well-being. Because constantly disturbing noises cause stress. Noise pollution can lead to chronic diseases of the hearing, the immune system and the cardiovascular system. For industrial buildings, therefore, special attention must be paid to compliance with sound insulation. Sound is the name given to all kinds of sounds that are in human perception.

State of the art

To reduce sound pressure levels in or on technical systems or their attachments or for use in or on buildings a variety of different solutions is known. The applied or published in patents constructions usually consist of a layer or filling which is made on the basis of fibrous materials and a facing shell which is designed according to the ambient conditions (heat, pressure, flow).

In order to achieve a high level of sound insulation, non-flammable and heat-resistant fibers such as mineral fibers or metal fibers are used in the areas of the (exhaust) gas guide, which are applied around the pipe in the form of sleeves or are flowed through or flowed through internally and usually in an apertured one Housing are integrated.

In the field of building installation or integration, the major part of the development in the combination of mineral foams, fibers, foams or minerals and a carrier layer of concrete, clay-containing materials, sheet metal or wood or woody compounds. Designs with openings in the direction of the sound source in the form of holes or slots for the penetration of sound into the core layers of dam materials are described in isolation.

In EP 00 001 781 A1 describes a method in which mineral fibers and metal fibers (basalt wool and stainless steel wool) for a sound-absorbing filling of mufflers are connected to a mat, this has a maximum binder content of 1%, which varies depending on the plate thickness, from one to the other Mattenseite shifted.

A sound absorbing body will be in DE 002 725 398 C2 described, consisting of a base of mineral fibers and a pulled over the base part tubular or bag-like structure.

A prefabricated sound-absorbing panel element suitable for wall cladding, which consists of elongated mineral fiber boards with a density of between 35 and 70 kg / m ³ as the core insulation and is surrounded by a cladding cassette consisting of sheet metal. The surface of the cover cassette can after DE 003 237 062 C2 also consist of a perforated plate.

A sound-absorbing wall with edge-sided metal profile stand, two-sided Plasterboard and central damping plate, which preferably consists of mineral wool, glass wool or plastic wool and on one side has a distance of at least one centimeter to the gypsum board, which is filled with, a mineral potting compound, which sets by hydration and a specific weight of about 1000 kg / m ³ has in DE 04 030 407 A1 described.

A sound absorbing element which consists of at least one sound absorbing mat (rock wool) in the core and is enclosed by a concrete shell, which is provided with holes and mostly with a textile reinforcement is in DE 100 21 443 A1 called. Due to the relatively evenly distributed holes over the surface of the sound can penetrate through the approximately 10 mm thick sound-facing surface in the sound-absorbing core. Furthermore, the concrete shell may have stiffening rib edging, which may also be made of textile reinforcements.

The system of a composite plate resonator with a vibrating plate made of solid material made of metal or plastic and a second vibrationally damping plate arranged behind it and made of mineral fibers is in DE 10 213 107 A1 disclosed. In this case, the vibrating plate can be arranged in a perforated metal frame or basket as well as a front or rear mounted additional porous absorber made of mineral fiber material.

A non - combustible sound absorber without mineral fiber with a broadband sound absorption, consisting of a metal frame and three layers of fiberglass fabric and attached directly to the reverberant boundary surface, is in DE 20 303 914 U1 described.

A heatable sound insulation panel, consisting of a sheet of synthetic foam, mineral wool or mineral foam and coated on one side with a mortar in which electrical heating elements are integrated, is installed in DE 20 2006 009 457 U1 called. The one or both sides applied mortar consists of a hydraulically setting or a resin-based binder.

In the DE 34 13 998 A1 Schalldämpfanlage described is characterized by an annular gap guide for gases. The inside of the boundary surfaces of the entire component and the inner tubes are sound-insulating and perforated, with stainless steel wool or mineral fibers are specified as a sound-absorbing material.

A suitable for particular flue gas desulphurisation muffler, are housed in the based on the absorption or resonance principle fillings and consist of resistant to acidic media plastic fibers, is in DE 34 21 484 A1 and DE 34 21 484 C2 wherein the fibers have a diameter of 2 to 20 microns and in the pressed state a longitudinal specific flow resistance of at least 3 kNs / m ⁴ . The filler may consist of polypropylene fibers which are solidified by a binder or by sintering into plates or felts and have a bulk density between 30 and 200 kg / m ³ .

Out DE 37 29 219 A1 and DE 37 29 219 C2 It is known that exhaust mufflers for internal combustion engines with at least one sound-absorbing, monolithic part of a porous mineral building material such as clay, brick clay, refractory clay, chamotte, a hydraulically or chemically ceramically bonded material, cement, concrete, aerated concrete or sand-lime brick, consist, the total porosity of the material is 50 to 90% with a pore size of 0.5 to 5 mm. Further, the porosity of the material decreases toward the outside of the entire component to the gas tightness on the outside.

A silencer backdrop with open lamellar plates to form outwardly open chambers which are filled with absorbent material and integrated into the backdrop meandering backdrop plates, which form a space filled with mineral fiber plates is in DE 38 01 867 A1 presented.

Composite material for heat and / or sound attenuation whose insulating layer consists of thermally stable, highly porous inorganic material is described in DE 39 05 871 A1 and DE 39 05 871 C2 wherein the insulating layer is a foamed inorganic material, a water glass whose water content is evaporated, foamed glass with a sponge-like structure, aerated concrete, foamed ceramic or clay mineral material, material of fibers or flakes (mica or graphite) or a closed-cell material may be.

In DE 43 30 129 A1 and DE 43 30 139 C2 is described an exhaust system of an internal combustion engine with pre and rear muffler, in which near the front and the rear muffler each a Helmholz resonator branches off, but which can also be integrated in one of the muffler housing. Further, the pre-muffler may be formed as an absorption damper, which has a sheath made of metal wool, in particular chromium steel wool or mineral wool, in particular basalt stone wool in the perforation. Of the Rear muffler may also be formed with a plurality of resonators flowed through.

A with exhaustive granules of natural minerals such as clay, sepiolite, gypsum od. Like. Filled and provided with sieves exhaust gas detoxifier is in DE 83 27 337.9 described.

Exhaust mufflers, such as main, middle, rear muffler or resonators for internal combustion engines is in DE 92 10 397 U1 wherein an intermediate material layer of reversible fiber material such as mineral fibers, glass fibers or mineral fibers is between 2 and 10 mm thick and a basis weight of 1500 to 7500 g / m ² or a density of 0.5 to 0.75 g / cm ³ and has a tensile strength of at least 0.1 N / mm ² .

At an in DE 196 35 804 A1 described muffler for internal combustion engines, the exhaust gas is passed through spaces in which granular mineral materials such. As expandable slate of a particular licensing are, which form a damping volume with sound-absorbing properties by filling.

In DE 197 12 835 A1 . DE 197 12 835 C2 and DE 197 12 835 C3 is a molded article of a lightweight material, which is formed from a lightweight aggregate and a sintering aid, wherein the sintered product 60 to 93 wt .-% of a lightweight aggregate and 40 to 5 wt .-% of a water-soluble silicate (alkali silicates, water glasses such as soda water or potassium silicate ) and is network-connected, has a dry bulk density of 150 to 750 kg / m ³ , a compressive strength of 0.1 to 15 N / mm ² and glass, pearls, expanded clay, expanded glass, vermiculite, natural or Metallurgical, Cenosperes and Diatomaceous earth can be. Furthermore, the use is mentioned as a building material, in particular as bricks, furnace lining, blocks for the formation of exhaust systems, for technical soundproofing indoors, for sound-absorbing segments for railways of rail vehicles, fire protection element and as a muffler in exhaust pipes.

A muffler for an internal combustion engine having improved acoustic performance at low and medium frequencies is disclosed in US Pat DE 60 2004 008 774 T2 described comprising an outer shell, an exhaust pipe, a dissipative silencer and a Helmholtz resonator and at least one baffle. The resonator contains porous, fibrous material (glass fibers, mineral wool fibers) that lines at least one wall

DE 26 27 801 A1 describes a sound damping device having a porous and / or perforated front plate, an nonporous plane or curve running back plate and a connecting core device which forms a plurality of resonator, wherein juxtaposed chamber walls have different porosities, so that they in groups the sound in different Absorb frequency ranges. But also the partitions of the individual chambers may have varying porosities in a second direction or may be perforated. Furthermore, woven and nonwoven organic or inorganic fibers that modify the acoustic properties may be adhered or welded to the intermediate walls.

Two rigid and freely vibrating layers and a flexible intermediate layer (felt), which are connected as an insulating plate in DE 26 53 388 A1 disclosed, wherein each rigid layer may have different thicknesses.

A load-bearing and sound-absorbing component with a thickness of at least 50 mm, is made by a rigid, open-cell structure produced by the formation of a starting material DE 27 52 343 A1 described, which has a porosity of 0.15 to 0.7 and an air flow resistance of 10 to 180 cgs units, called. In this case, the starting material may be sand, flint or granite, it has a maximum particle size of 0.5 to 2 mm, with a hardenable resin binder (polyurethane, epoxy, or unsaturated polyester resins), sodium silicate or a phosphate binder is bound. Furthermore, an element according to the invention with a bead of 100 mm absorbs and isolates frequencies of 100 to 10 ⁴ Hz. The back has a relatively non-porous layer of gypsum, cement or polyurethane foam.

A soundproofing panel consisting of a plastic hollow section and whose cavity is filled with a cement consisting essentially of at least one filler and / or aggregate, volcanic glass rock in granular form (Staupex), plastic flakes or pearls (Perlith) or sand, is in DE 27 55 027 A1 mentioned.

A haufwerksporige, sound-permeable and acting as a protective filter layer of a Schallschluckverkleidung is in DE 29 05 067 A1 mentioned, wherein the layer of grains such as gravel, chippings, ceramics, metals or plastics, a grain size of 2 to 40 mm and made with cement bond, plastic bond or refractory bonding material.

A multi-layer system of a soundproofing hood will be installed in DE 29 13 715 A1 described, wherein at least one layer of a cement or the like. Bound wood chipboard is composed and with a Cavity is provided with z. B. mineral fibers can be filled. A very similar system is also in DE 32 15 257 A1 called.

A sound-absorbing wall element consisting of outer vibratable air-permeable plate elements and a second air-permeable (evenly distributed holes) plate element is in DE 29 46 392 C2 whose elastic moduli are greater than 10 ⁹ N / mm ² . The gap of these plates may be filled with a porous material or may have a honeycomb structure.

An in DE 36 32 394 C2 and DE 86 25 477 U1 said production method for noise protection elements produced in a sound-absorbing layer of luminous by the placement or flow around a shaped grate slats a superficial profiling, which faces the noise source.

An existing from a ribbed construction element for building structures whose interspaces are provided with an insulation is in DE 39 14 942 A1 described, wherein the surface recesses (holes, slots), which are designed sound absorbing or as Helmholzresonator with an open resonator.

On a device applied and forming an air gap Haufwerksporige and sound-absorbing plates are in DE 42 31 487 A1 disclosed.

A sound reduction element for a track system made of several materials or mixtures of the group sand, gravel, chippings, concrete, pumice stone, expanded clay, with cement or adhesive bindable aggregates, cement or artificial adhesive is in DE 94 17 008 U1 Also known are shaped bodies of hesswerksartigem and porous concrete, densities of 1 to 1.2 kg / dm ³ , compressive strengths of 10 to 100 N / mm ² and a profiled surface.

An in DE 299 11 495 U1 described sound absorbing plate made of wood or wood-like material is provided with holes with a diameter smaller than 1.5 mm, the micro perforations are on a supporting layer (eg cementitious particles) arranged with passages. Further, pits are called behind the microperforation.

A sound-absorbing plate-shaped element made of wood, a wood-like or wood-like material, plastic, building material such as clay, gypsum, concrete, natural or artificial stone, masonry combinations or combinations thereof with a plurality of recesses is in the Scriptures DE 10 2004 040 112 A1 called, wherein the recesses taper with increasing cross-section. Further, the recesses in a sound-absorbing layer (fleece, foam, porous absorber) open directly or at a distance.

In DE 10 2006 020 763 A1 is a sound-absorbing component called with an attachment shell of sound-absorbing material that is covered one or two sides. The support plate can be cast as a concrete support shell, fiberglass concrete or plastic plate.

Absorbers consisting of two or more porous layers with a sound-facing higher-density or stiffened layer, which are foams, fiber materials, minerals, glass materials, ceramics, plastics, metals or aerated concrete. The higher density perforated or slotted layer is selectively or flatly connected to the other layer.

Differences between the patents mentioned arise from the external and internal design (insulation arrangement, arrangement of the air flow paths, frequency filter types).

All of the foregoing described solutions in their entirety do not meet the requirements of a universal, modular and suitable for low frequencies sound insulation without integrated core insulation of fiber, foam or minerals.

task

The invention is based on the object to provide a component, in particular a sound-absorbing wall or ceiling element, that by the arrangement of an absorber a significant reduction of the sound reflection of the sound source side facing and a significant increase in the total sound insulation for broadband, especially for low frequencies is effected, which can be dispensed with the use of fiber, foam, dams or other not related to the binder system of the support structure group of substances.

The solution of this object is achieved according to the features of claim 1. Advantageous developments are described in the subclaims.

It is essential for the invention that an absorber is created by a multi-layer arrangement, consisting of a layer with porous properties, an air layer and a third, reverberant layer, which can also be formed as a support layer, which nevertheless without the use of conventional fiber , Foam or Dammstoffe is produced and can be used as a broadband absorber, in particular as a low-frequency absorber.

The first porous layer of the sound absorbing device is characterized in that it is plate-shaped, at least the mixture of a water-solidifying binder (lime, cement, gypsum, clay, etc.), natural or artificial aggregates and for solidification or hardening The binder necessary water is produced so that a hovwerksporige structure arises. By way of example, this structure having a honeycomb structure can be designed as a hovel-spoked concrete, the design with light aggregates being advantageous. This porous layer may furthermore have a porosity which is changed over the thickness of this layer, so that changed flow resistances or a flow-tight termination result in the same way.

There are now a variety of ways to design the sound absorption element according to the invention or the inventive sound absorption device in an advantageous manner and further. In the following, several preferred embodiments of a sound absorption device according to the invention will now be described with reference to the following embodiments and the accompanying drawings.

Embodiment 1:

The absorber according to the invention consists of a first layer, which is designed so that behind it in a quasi-second layer results in an air-filled cavity and a third layer, which may be designed as a support layer.

In one embodiment, the first sound attenuation element consists of a microperforated layer ( 3 ), which has such a porosity that an air exchange with the airspace arranged behind it is possible. The airspace behind it ( 1 ) acts as a resonator from now on.

Since the sound waves in one embodiment of the sound absorption device initially on the first porous sound attenuation element ( 3 ) meet with said properties, the sound waves are partially absorbed or less reflected, so that the reverberation of a noise in a room or a hall is reduced.

Embodiment 2:

Since, in the first embodiment, due to the porosity of said layer, an incomplete volume of space is formed, the effectiveness of the resonator against low frequencies decreases.

This results in a second, preferred embodiment of the sound absorption device, a reverberant and completely flow-tight layer ( 4 ), which faces away from the sound source and the air space facing surface of the first porous sound attenuation element is arranged.

Furthermore, the first porous layer, hermetically sealed off on the inside of the air space, has at least one recess (FIG. 2 ), which is advantageously round or slit-shaped, so that a resonator volume ( 1 ) shows that, with the exception of the recess ( 2 ) from the surfaces of the first sound attenuation element ( 3 ) and the reverberant layer ( 5 ) is limited.

Particularly for the embodiment of an embodiment of the opening (s) is that the flanks of the recesses airtight, so superficially closed, can be designed to achieve optimum resonance tuning.

The sound waves are partly swallowed or less reflected by this porous sound attenuation element with the properties mentioned, so that the reverberation of a noise in a room or a hall is reduced or the sound absorption is increased. Furthermore, the sound waves are partially transmitted via the recess (s) into the cavity, where they are absorbed in an air space, a resonator, which is of a torsionally rigid layer, which may for example be designed as a support or as a construction layer. Thus, there is an interaction of the sound waves through the opening (s) with the volume of air.

It is particularly for this embodiment that results from the aforementioned manner a resonator, which can be adjusted by varying the air volume, the air layer thickness, length, design or geometry of the resonator opening in its resonant frequency. The change in the volume of air can be done by changing the distance or the lateral boundaries between the first absorption element and the reverberant surface.

The absorption can be considered frequency-specific or broadband by the respective design and the respective area ratio from the combination of the sound absorption elements according to the invention or the sound absorption devices.

1 shows a schematic representation of the essential parts of a sound absorber in one embodiment, the same elements in T-shape.

2 shows a schematic representation of an embodiment, wherein the geometric shape of the sound absorbing element is similar to a U-shape and forms a slot resonator. This embodiment can be manufactured as a finished part and suitably combined with one another and connected or fastened. In this case, elements with a three-sided volume limitation can be combined with elements of a two-sided volume limitation.

3 shows a schematic representation of the preferred embodiment, wherein the flanks of the recess and the resonator forming surfaces of the sound absorbing element are designed to be flow-tight.

LIST OF REFERENCE NUMBERS

1

air volume

2

resonator opening

3

Sound absorption element

4

fluid-tight layer

5

flow-proof surface (eg support or construction layer)

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

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Claims (9)

A sound absorbing device comprising a spaced, planar absorption element for attachment, integration or combination to or with a flow-tight surface, which may be formed as a support or construction layer and an intermediate cavity, free of fiber, foam and dams or other fillers is characterized in that the spaced sound absorbing member has a porous structure which is bound from a mixture of natural and / or artificial aggregates and an organic or inorganic binder and the necessary for the setting of the binder water or hardeners and additives and / or additives , Sound absorption device according to claim 1, characterized in that the porous structure is open to flow. Sound absorption device according to claim 1 and 2, characterized in that the porous structure on the side facing away from the sound source has a flow-tight layer. Sound absorption device according to claim 1 and 3, characterized in that the porous structure has recesses which are round or slit-shaped and can be designed to be flow-tight on the flanks. Sound absorption device according to claim 1, characterized in that the porous structure is a haufwerksporiger lightweight concrete or hovwerksporiger concrete. Sound absorption device according to claim 1 and 5, characterized in that the porous structure is solidified on the basis of an inorganic or organic binder. Sound absorption device according to claim 1, characterized in that the planar absorption element has elevations which correspond to the spacing and with lateral, flow-tight boundaries generate a defined volume of air to the reverberant surface. Sound absorption device according to claim 1 and 7, characterized in that the flat absorption element alone or in combination with other embodiments of the absorption elements generates a defined volume of air between the absorption elements and a further flow-tight surface. Sound absorption device according to claim 1 and 8, characterized in that the element by means of adhesive, dowels, anchors, bolts, rods, Frisch-in-Frisch process or other suitable fastening measures is attached to a flow-tight surface.

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