(19)
(11)EP 0 521 657 A1

(12)EUROPEAN PATENT APPLICATION

(43)Date of publication:
07.01.1993 Bulletin 1993/01

(21)Application number: 92305858.0

(22)Date of filing:  25.06.1992
(51)International Patent Classification (IPC)5E04B 1/86
(84)Designated Contracting States:
BE CH DE DK ES FR GB IT LI NL SE

(30)Priority: 03.07.1991 GB 9114408

(71)Applicant: HUNTER DOUGLAS INDUSTRIES B.V.
NL-3071 EL Rotterdam (NL)

(72)Inventor:
  • Rijnders, Willem
    NL-3352 XH Papendrecht (NL)

(74)Representative: Allen, William Guy Fairfax et al
J.A. KEMP & CO. 14 South Square Gray's Inn
London WC1R 5LX
London WC1R 5LX (GB)


(56)References cited: : 
  
      


    (54)Sound absorbent material


    (57) Sound absorbent building panel or strip material comprises a substantially rigid panel body (1) having a plurality of apertures (3) therein and a relatively thin layer of porous fabric (2) being applied to said rigid panel body in such a manner that it covers the apertures (3) therein, said porous fabric having a density defining pores that are substantially smaller than at least some of the apertures in said panel, the fabric layer (2) being bonded to the panel body (1) by means of adhesive material, applied in an open convoluting pattern along multiple adjacently spaced longitudinal tracks (4).




    Description


    [0001] The present invention relates to a sound absorbent material which may, for example, be used in the fabrication of building panels for uses such as ceiling and partition panelling.

    [0002] GB-A-2133431 (Schmidt, HJ) relates to a building panel or metal strip material therefor comprising an apertured rigid panel body covered with a porous fabric.

    [0003] The problem experienced while bonding such porous fabric to a painted metal substrate is that the adhesive material tends to clog the pores of the fabric material which adversely effects the acoustic properties.

    [0004] There is also a problem that the adhesive if applied to any excessive quantities shows through the fabric and contaminates the apertures in the perforated sheet metal.

    [0005] Several methods of applying adhesive (commonly of the hot-melt type) have been tried, but none so far has been found entirely.satisfactory. It has been generally found that applying adhesive in an open pattern of beads or dots provides adequate bonding of a particular fabric or fibrous material without unduly reducing porosity.

    [0006] One technique for obtaining an open adhesive pattern is disclosed in WO 88-10154 (Nordson Corp.) and has been applied to moisture absorbing laminates.

    [0007] This method provides for a plurality of convoluting beads in a side by side arrangement, each bead being constrained to a track of predetermined width so as to form a multiple of adjacently spaced longitudinally extending tracks along the length of a web.

    [0008] The efficiency of thin layer materials in providing sound absorbing qualities has been attributed to the airflow resistance through such material. However, the low weight of the material requires it to be firmly attached around the apertures of a rigid panel body to obtain the best results.

    [0009] According to the present invention, there is provided sound absorbent building panel or strip material comprising a substantially rigid panel body having a plurality of apertures therein and a relatively thin layer of porous fabric being applied to said rigid panel body in such a manner that it covers the apertures therein, said porous fabric having a density defining pores that are substantially smaller than at least some of the apertures in said panel, wherein the fabric layer is bonded to the panel body by means of adhesive material, applied to an open convoluting pattern along multiple adjacently spaced longitudinal tracks.

    [0010] The term "rigid body panel" is to be read to include any form of such panel material including building panels which may be used as ceiling panels or in portioning, as well as other panels such as sheets, tiles or planks.

    [0011] By adaption of the density of the adhesive spray pattern and the bead thickness it has been proven possible to achieve the desired adhesive density for bonding porous sound absorbent substrates to perforated panel material without loss of acoustic properties.

    [0012] This has been achieved by positioning the tracks of convoluting beads more closely together while arranging for a small uncovered area between adjacent beads.

    [0013] The substrate may be of a substantially rigid material. The fabric, on the other hand, should be relatively thin and porous, a particularly suitable material being Freudenberg VILEDON C 1986.

    [0014] For secure adhesion of the fabric, the number and width of said tracks should be such that the tracks accounts for between 50 to 100 percent, more preferably 62 to 87 percent, of the width of the fabric.

    [0015] Preferably, the adhesive is applied in a bead having a thickness not exceeding 0.035 mm and the fabric has a resistance to airflow of over 100 NS/m³ (DIN 52213).

    [0016] In one form, the apertures in said panel body are formed as circular holes of 1 mm diameter, spaced at 2 mm in a triangular pattern.

    [0017] Preferably, the porous fabric is a non-woven type fibrous substrate, more particularly, one whose substrate comprises randomly arranged cellulose and glass fibre with a synthetic resin binder having a resistance to airflow of at least 140 NS/m³ (DIN 52213).

    [0018] A suitable hot-melt type of adhesive has a viscosity of less than 1800 cP (centi Poise) at temperatures above the softening point.

    [0019] Preferably, the overall adhesive density is less than 15 g/m² (gram per square meter) of fabric.

    [0020] Conveniently, successive circles or ovals of the tracks, in the longitudinal direction of said fabric, overlap one another by an amount of 14 to 60 percent of their dimension in said longitudinal direction.

    [0021] In order that the present invention may more readily be understood, the following description is given, merely by way of example, reference being made to the accompanying drawings in which:-

    Figure 1 shows, somewhat schematically, part of one embodiment of sound absorbent building panel embodying the present invention; and

    Figure 2 shows the track pattern which a hot-melt adhesive spray machine was programmed to follow in order to lay out the adhesive bead track pattern used in the production of the panel of Figure 1.



    [0022] Before describing the manner of production of the panel of Figure 1, its structure will be briefly described.

    [0023] The panel is formed from a metallic substrate 1 having slots or apertures 2 therein and a non-woven fabric 3 applied to one or more of its major faces in such a manner that the fabric 3 lies on the substrate 1 in a stretched and non-detachable manner at all locations and is stretched over the slots or apertures 2. The non-woven fabric produces in the region of the apertures in the panel an increased resistance to air flow and thereby produces the desired sound absorbability of the panel or panel material. The substrate may be of metal, wood, cardboard or plastics and the fabric 2 of woven, knitted or non-woven.

    [0024] The equipment used was obtained from Nordson but is used in a modified set-up to achieve a smaller spacing of the adjacent tracks.

    [0025] The panel illustrated is formed as follows:-
       First, the apertures or slots are formed, e.g., by stamping, in the case of a sheet metal substrate, and then the surface of the substrate is prepared (if necessary, or desirable, having regard to its material) for example by application of a layer of paint in the case of sheet metal.

    [0026] Hot-melt adhesive is then applied to the surface of the fabric 2 (or substrate 1) by spraying using a machine of the type described in the Nordson Publication WO 8810154.

    [0027] The track pattern of the adhesive beads laid down by the spraying machine is shown in Figure 2. It will be seen that there are a number of closely spaced tracks 4 parallel to an edge of the panel, each track 4 corresponding to the path described by an adhesive bead being rotatingly deposited about the centre line of the track while translating the centre of rotation at a constant linear velocity; the relationship between the linear velocity and the rotational velocity of the spray head is such as to produce the spiral track areas as shown in Figure 2. The spray nozzles are shown as a plurality of nozzles 10 mounted on a spray bar 12 which is movable back and forth over the panel 1, along a path indicated by the double arrows 14. It will be seen that the spray bar 12 is inclined at an angle α to a line 16 perpendicular to the direction of movement 14 of the spring bar 12.

    [0028] It will be noted that there are several spiral tracks 4, one for each spray nozzle. It has been found that a satisfactory density of adhesive can be provided if these tracks 4 do not overlap, thus ensuring that the adhesive does not have any excessive build-up. The spacing of the tracks 4 can be adjusted by adjusting the angle α of the spray bar 12 carrying the nozzles 10.

    [0029] The rotating effect can be achieved by rotating the nozzle itself and/or by rotating an annular stream of gas (usually air) around the stream of adhesive leaving each nozzle. The rotational direction of the nozzles and/or air streams can be the same or can, for example, alternate from one direction to the opposite.

    [0030] Once the adhesive has been applied, the fabric is pressed, in a suitably tensioned state firmly against the substrate and maintained in that condition while the adhesive cures or sets.

    [0031] It has been found that with the panel, strip or sheet material of the invention, the efficiency of thin layer porous fabric materials in providing sound absorption depends largely on the airflow resistance through such materials. Being of low weight, satisfactory results can only be obtained if the non-woven sound absorbing fabric is firmly attached around the apertures of the perforated panel, strip or sheet.

    [0032] Achieving an adequate adhesive bond in volume production, has previously presented problems in that the adhesive not only tends to clog the pores of the non-woven, but also shows through and contaminates the apertures in the perforated strip. It has proved extremely difficult if not impossible to confine the adhesive to the areas between the apertures of the strip.

    [0033] With the open convoluting or swirl pattern of overlapping circles the structure of the invention has proven successful in avoiding excessive build-up of adhesive while making the best possible use of the sound absorbing properties available in the fabric, e.g., a non-woven fabric by adequate density of bonding.


    Claims

    1. A sound absorbent building panel or strip material comprising a substantially rigid panel body (1) having a plurality of apertures (3) therein and a relatively thin layer of porous fabric (2) being applied to said rigid panel body in such a manner that it covers the apertures (3) therein, characterised in that said porous fabric (2) has a density defining pores that are substantially smaller than at least some of the apertures in said panel, in that the fabric layer (2) is bonded to the panel body (1) by means of adhesive material, applied in an open convoluting pattern along multiple adjacently spaced longitudinal tracks (4).
     
    2. Material according to claim 1, characterised in that the number and width of said tracks (4) is such that the tracks account for between 50 to 100 percent of the width of the fabric.
     
    3. Material according to claim 2, characterised in that the number and width of said tracks is such that the tracks account for between 62 to 87 percent of the width of the fabric.
     
    4. Material according to claim 1, 2 or 3, characterised in that the adhesive is applied as a bead having a thickness not exceeding 0.035 mm and the fabric has a resistance to airflow of over 100 NS/m³ (DIN 52213).
     
    5. Material according to any one of the preceding claims, characterised in that the arrangement, size and number of apertures in said panel body is in a ratio of 10 to 30 percent of the total surface.
     
    6. Material according to any one of the preceding claims, characterised in that the adhesive is a hot-melt type of adhesive.
     
    7. Material according to claim 6, characterised in that the hot-melt type of adhesive has a viscosity of less than 1800 cP (centi Poise) at temperatures above the softening point.
     
    8. Material according to any one of the preceding claims, characterised in that the convoluting pattern of the tracks (4) is a swirl pattern forming an array of overlapping circles or spirals.
     
    9. Material according to claim 8, characterised in that successive circles or spirals in the longitudinal direction of said track overlap one another in an amount of 14 to 60 percent of their dimension in said longitudinal direction.
     
    10. Material according to any one of the preceding claims, characterised in that the apertures in said panel body are formed as circular holes of 1 mm diameter, spaced at 2 mm in a triangular pattern.
     
    11. Material according to any one of the preceding claims, characterised in that the overall adhesive density is less than 15 g/m2 (gram per square meter) of fabric.
     
    12. Material according to any one of the preceding claims, characterised in that the porous fabric is a nonwoven type of fibrous substrate.
     
    13. Material according to claim 12, characterised in that the non-woven fibrous substrate comprises randomly arranged cellulose and glass fibre with a synthetic resin binder having a resistance to airflow of at least 140 NS/m³ (DIN 52213).
     




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