GB2386935A

GB2386935A - Ducting with sound absorbing properties

Info

Publication number: GB2386935A
Application number: GB0304086A
Authority: GB
Inventors: Diane Gibson
Original assignee: Smiths Group PLC
Current assignee: Smiths Group PLC
Priority date: 2002-03-15
Filing date: 2003-02-24
Publication date: 2003-10-01
Anticipated expiration: 2023-02-24
Also published as: ES2260528T3; EP1344969B1; US6679296B2; US20030172981A1; ATE325979T1; GB0304086D0; DE60305088T2; EP1344969A3; GB0206074D0; DE60305088D1; EP1344969A2; GB2386935B

Abstract

Sound attenuating ducting has an inner, helical wire 1 supporting an inner and outer layer 2 and 7 formed by strips 3 and 8 of a foamed thermoplastic rubber material. Axial and helical reinforcing yarns 5 and 6 extend along the ducting between the layers 2 and 7. The two strips 3 and 8 are applied from extruders, the extrusion rate of the inner strip being set to be less than that of the outer strip so that the inner strip is stretched to produce a more porous structure than in the outer strip. In this way, the inner layer 2 is efficient in absorbing orifice noise within the ducting and the outer layer 7 contains radiated noise.

Description

1 2386935

DUCTING

This invention relates to ducting.

The irivention is more particularly concerned with ducting having sound absorbing properties. Ducting with sound absorbing properties is often used in applications where it extends from a high noise environment, so as to prevent transmission of this noise. To achieve the greatest sound absorbing properties, the ducting should have a high attenuation of orifice noise, that is, noise transmitted along the length of the ducting through its bore, and a high attenuation of radiated noise, that is, noise transmitted through the wall of the ducting. It is difficult to provide low cost, lightweight ducting having a high attenuation of both orifice and radiated noise. In some cases, the ducting may require greater orifice attenuation and lower radiated attenuation, whereas in other cases the ducting may require greater radiated attenuation and lower orifice attenuation. The need to make specialised ducting for these different applications adds to the cost of manufacture. Ducting can be provided with an inner layer of a sound absorbing foam, such as described in GB2218772. In this previous ducting, overlapping parts of a helical foam strip are crimped into a helical metal channel and this is covered by an outer impervious sleeve shrunk about the channel.

It is an object of the present invention to provide improved ducting.

According to the present invention there is provided ducting comprising an inner support member of helical shape, a first layer wound helically about the outside of the support member and bonded thereto, and a second layer wound helically about the outside of the first layer, the first and second layers being both of a permeable, open cell thermoplastic rubber material.

The first layer preferably has a substantially higher permeability than the second layer. The first layer may have a multiplicity of holes between 2mm and 3mm in width, the second layer having fewer, smaller holes less than about lmm in width. The first and second layers are preferably of substantially the same chemical composition. The first and second layers are preferably produced by extrusion and the extrusion output of the first layer is preferably lower than that of the second layer. The first layer may be wound onto the inner support member while warm so that it bonds with the support member. The first layer may be provided by a strip wrapped on the inner support member with the same pitch and overlapping approximately half the width of adjacent turrets. The inner support member may be a plastic-coated wire. The ducting may include a plurality of yarns of non-elastic material extending axially along the ducting between the two layers. The ducting may include a yarn of non-elastic material extending helically around the ducting between the two layers, which is preferably wound on top of the axially-extending yarns.

Sound-attenuating ducting according to the present invention will now be described, by way of example, with reference to the accompanying drawing, in which: Figure 1 is a partly cut-away side elevation view of the ducting;

Figure 2 is an end view of the ducting along the arrow II of Figure 1; Figure 3 is an enlarged side elevation view showing parts of the two layers stripped back; and Figure 4 is an enlarged cross-sectional side elevation view of a part of the ducting. The ducting comprises an inner support member in the fom1 of a plastic-coated steel wire 1 wound into a helical configuration. The wire 1 is stiff enough to provide the main structural support of the ducting whilst enabling the ducting to be flexed and to be compressed axially. Typically, the wire 1 has a diameter of lmm and is wound into a helix having a diameter of about 80rnm and a pitch of about 1 Len. It will be appreciated that the ducting could have a range of different diameters, typically front about 60mm to 80mm, and that the diameter and pitch of the wire can also be varied The wire 1 supports a covering including an inner layer 2 of a chemically foamed EPDM/PP based themmoplastic rubber. The layer 2 is fommed by a strip 3 about 24mm wide, which is wrapped helically with the same pitch as the wire 1 so that it overlaps about half the width of adjacent turns. The strip 3 is extruded and is wrapped on the wire 1 while it is still warm, so that it bonds with the wire and with adjacent turns of the strip. Alternatively, the strip 3 could be extruded and stored in roll form before being wrapped on the wire at a later stage. In this case, an adhesive or solvent would be needed to bond the strip to the wire. The

inner strip 3 is extruded at a relatively low output so that the foamed melt is stretched as it is wound on the wire 1. This gives the material an open cell structure, where the cell pockets are highly fractured, so that the layer 2 has a multiplicity of holes 4 of width up to 2-3mm. This makes the inner layer 2 highly porous.

The ducting has eighteen thin yarns 5 of nylon, or a similar high strength, non-elastic material, extending axially along the duct on top of the inner layer 2 and equally spaced around the duct. The purpose of these yarns 5 is to act as an axial reinforcement, that is, to prevent axial extension of the ducting; different amounts of yams could be used. The ducting also has a two further yarns 6 of the same material, which are wrapped helically around the duct, on top of the inner layer 2 and crossing the axial reinforcement yarns 5, between the turns of the wire 1. The purpose of these further yarns 6 is to provide a helical reinforcement, that is, to help prevent twisting of the duct and to pull down the axial yarns 5 into the valleys between the turns of the wire 1.

The final component of the ducting is a second, outer layer 7, which is of the same chemically foamed thermoplastic rubber material as the inner layer 2. The outer layer 7 is provided by a strip 8 of the same width as the inner strip 3 and wound in the same manner as the strip 3 of the inner layer. The strip 8 is extruded at the same temperature as the inner strip 3 but at a higher output, so that the foamed melt is not stretched as much as the inner strip when it is wound onto the ducting. The outer layer 7 still has an open cell structure but the higher output means that the cell pockets are unfractured so that the layer has only a low porosity, with few holes and these being less than lmm in width. The outer strip 8 is wound helically parallel to the inner strip 3 on top of the reinforcing yams 5 and 6. The outer strip 8

is extruded directly onto the inner strip 3 so that it bonds with it and traps the yarns 5 and 6 in position. The dueling can be made simply on conventional machines.

The very porous nature of the inner layer 2 enables it to absorb orifice noise highly efficiently, whereas the less porous nature of the outer layer 7 also absorbs the orifice noise, but less efficiently, and is sufficiently non-porous to contain the radiated noise and to a greater extent than the inner layer. The combination, therefore, of the two porous layers 2 and 7 ensures that the wall of the duct absorbs a high amount of noise, giving it a high attenuation of both orifice noise and radiated noise. Although both layers 2 and 7 are porous, the dueling is generally used in low pressure, high volume applications so there is very little escape of gas through the wall of the duct. The construction of the ducting enables it to retain sufficient flexibility, to be light in weight and to have a low cost of manufacture. The inner and outer layers are compatible and can be bonded together easily because they have the same chemical composition. Although the maximum noise attenuation is achieved by the combination of the inner and outer layers of different porosity, in some applications, it may be preferable for the duct to have a high orifice noise attenuation but a lower radiated noise attenuation is acceptable. In these circumstances, the duct could be made with both the inner and outer layers having the same, high porosity. On the other hand, if the application requires a high attenuation of radiated noise but a lower attenuation of orifice noise is acceptable, the duct could be made with both the inner and outer layers having the same, low porosity. The ducting can,

therefore, easily be tailored to individual requirements simply by the choice of materials, or extrusion rates of the materials, from which the inner and outer strips are made.

Claims

1. Ducting comprising an inner support member of helical shape, a first layer wound helically about the outside of the support member and bonded thereto, and a second layer wound helically about the outside of the first layer, the first and second layers being both of a penneable, open cell thermoplastic rubber material.

2. Ducting according to Claim 1, wherein the first layer has a substantially higher

permeability than the second layer.

3. Ducting according to Claim 2, wherein the first layer has a multiplicity of holes between 2mm and 3mrn in width, and wherein the second layer has fewer, smaller holes less than about lmm in width.

4. Ducting according to any one of the preceding claims, wherein the first and second layers are of substantially the same chemical composition.

5. Ducting according to any one of the preceding claims, wherein the first and second layers are produced by extrusion.

6. Ducting according to Claim 5, wherein the extrusion output of the first layer is lower than that of the second layer.

7. Ducting according to Claim 5 or 6, wherein the first layer is wound onto the inner support member while warm so that it bonds with the support member.

8. Ducting according to any one of the preceding claims, wherein the first layer is provided by a strip wrapped on the inner support member with the same pitch and overlapping approximately half the width of adjacent sums.

9. Ducting according to any one of the preceding claims, wherein the inner support member is a plastic-coated wire.

10. Ducting according to any one of the preceding claims including a plurality of yarns of non-elastic material extending axially along the ducting between the two layers.

11. Ducting according to any one of the preceding claims including a yam of non-elastic material extending helically around the ducting between the two layers.

12. Ducting according to Claims 10 and 11, wherein the helicallyextending yam is wound on top of the axially-extending yarns.

13. Ducting substantially as hereinbefore described with reference to the accompanying drawing.

14. Any novel and inventive feature or combination of features as hereinbefore described.