A sound attenuation mechanism made up of multiple substrate layers, including corrugated layers. The use of corrugation provides an inexpensive and manner of forming a plurality of highly effective acoustic attenuation channels throughout the mechanism. The multi-layered mechanism may be provided in
A sound attenuation mechanism made up of multiple substrate layers, including corrugated layers. The use of corrugation provides an inexpensive and manner of forming a plurality of highly effective acoustic attenuation channels throughout the mechanism. The multi-layered mechanism may be provided in a variety of modular forms and sizes which may be combined to form a low-cost, highly effective attenuation housing. For example, such a housing may be utilized to contain otherwise noisy large scale oilfield equipment such as coiled tubing engines. Additionally, where drainage from the housing is sought, a spiraled attenuation channel may be employed such that the effectiveness of the attenuation provided by the housing is not sacrificed.
대표청구항▼
1. A sound attenuation mechanism comprising: a first corrugated substrate layer; anda second corrugated substrate layer adjacent said first corrugated substrate layer, each of the layers defining concave portions separated by flat regions therebetween, the layers welded together at their respective
1. A sound attenuation mechanism comprising: a first corrugated substrate layer; anda second corrugated substrate layer adjacent said first corrugated substrate layer, each of the layers defining concave portions separated by flat regions therebetween, the layers welded together at their respective flat regions to form a plurality of acoustic attenuation channels between the concave portions thereof, wherein at least one of the first or second corrugated substrate layers comprises a plurality of inlets aligned with a plurality of concave surfaces of said first or second corrugated substrate layers, the inlets and the concave surfaces are aligned such that the attenuation channels are substantially perpendicular to the sound being attenuated. 2. The sound attenuation mechanism of claim 1 further comprising: a third corrugated substrate layer adjacent said second corrugated substrate layer; anda fourth corrugated substrate layer adjacent said third corrugated substrate layer to form another plurality of acoustic attenuation channels therebetween. 3. The sound attenuation mechanism of claim 1 wherein the sound attenuation channels are one of cylindrical, oval, triangular, rectangular, polygonal, and irregularly elliptical-like. 4. The sound attenuation mechanism of claim 1 further comprising fibrous material filling the attenuation channels. 5. The sound attenuation mechanism of claim 4 wherein said fibrous material is one of wool character, fiberglass, elastic, and an impermeable media. 6. The sound attenuation mechanism of claim 1 configured for attenuation of sound of a predetermined magnitude. 7. The sound attenuation mechanism of claim 1 further comprising plates for encasing said layers to provide the mechanism in modular wall form. 8. An assembly comprising: noise generating equipment; anda sound attenuation housing containing the noise generating equipment, said housing having a wall of encased corrugated substrate layers, wherein at least two of the corrugated substrate layers welded together to form a plurality of acoustic attenuation channels therebetween, the channels filled with a fibrous material and oriented perpendicularly to the noise generating equipment. 9. The assembly of claim 8 wherein said noise generating equipment is an engine configured to generate over 100 dB of noise during operation and said housing is configured to attenuate the noise down to less than about 85 dB. 10. The assembly of claim 9 further comprising a coiled tubing pump coupled to a reel of coiled tubing for an application in a well at an oilfield, the engine being a diesel engine coupled to said pump for powering the application. 11. The assembly of claim 8 wherein said plurality of sound attenuation channels being configured to attenuate noise arriving from the noise generating equipment in a radial direction with respect to a longitudinal axis of the sound attenuation channels. 12. A sound attenuation housing comprising: a wall of substrate layers with a corrugation forming a plurality of acoustic attenuation channels between said layers; andan attenuation drain defining a channel therein, the channel comprising a continuous chanelled spiraling therein to attenuate noise within the drain, the drain running from said wall for allowing fluid to leave the housing. 13. The sound attenuation housing of claim 12 wherein said wall and said drain are each configured to afford the housing attenuation of a noise therein of greater than about 100 dB down to less than about 85 dB. 14. The sound attenuation housing of claim 12 wherein said plurality of acoustic attenuation channels being configured to attenuate noise along a longitudinal axis of the plurality of acoustic attenuation channels. 15. A method comprising: corrugating a first substrate layer, the first layer defining concave portions separated by flat regions therebetween:corrugating a second substrate layer, the second layer defining concave portions separated by flat regions therebetween;welding the second substrate layer to the first substrate layer at their respective flat regions and at interfaces of the concave portions and forming a plurality of acoustic attenuation channels therebetween; andemploying the coupled layers for attenuating a noise of a noise generating equipment by orienting the channels substantially perpendicular to the noise of the noise generating equipment. 16. The method of claim 15 further comprising: corrugating a third and fourth substrate layer;coupling the third substrate layer to the second and fourth substrate layers in a manner forming another plurality of acoustic attenuation channels between the second and third substrate layers, and between the third and fourth substrate layers;aligning the first, second, third and fourth corrugated substrate layers relative to the acoustic attenuation channels; andencasing the first, second, third and fourth corrugated substrate layers in plates to form a modular wall prior to employing. 17. The method of claim 16 further comprising: forming a housing using the modular wall; andpositioning the noise generating equipment in the housing prior to employing. 18. The method of claim 17 wherein the noise generating equipment includes an engine for powering an oilfield application. 19. The method of claim 18 wherein the noise from the engine is over about 100dB in the housing, the plurality of acoustic attenuation channels configured to reduce the noise to below about 85 dB outside of the housing. 20. A method of reducing noise of an oilfield operation, comprising: using a sound attenuation mechanism, comprising: a first corrugated substrate layer; anda second corrugated substrate layer adjacent said first corrugated substrate layer, each of the layers defining concave portions separated by flat regions therebetween, the layers welded together at their respective flat regions to form a plurality of acoustic attenuation channels between the concave portions thereof;wherein using comprises orienting the channels substantially perpendicular to the sound being attenuated. 21. The method of claim 20 further comprising positioning the sound attenuation mechanism near a noise generating equipment. 22. The method of claim 20 wherein at least one of the first or second corrugated substrate layers of the sound attenuation mechanism further comprises a plurality of inlets aligned with a plurality of concave surfaces of said first or second corrugated substrate layers. 23. The method of claim 20 wherein the sound attenuation mechanism further comprises a third corrugated substrate layer adjacent said second corrugated substrate layer; and a fourth corrugated substrate layer adjacent said third corrugated substrate layer to form another plurality of acoustic attenuation channels therebetween.
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