NZ624135B2 - Acoustic dampener - Google Patents
Acoustic dampener Download PDFInfo
- Publication number
- NZ624135B2 NZ624135B2 NZ624135A NZ62413512A NZ624135B2 NZ 624135 B2 NZ624135 B2 NZ 624135B2 NZ 624135 A NZ624135 A NZ 624135A NZ 62413512 A NZ62413512 A NZ 62413512A NZ 624135 B2 NZ624135 B2 NZ 624135B2
- Authority
- NZ
- New Zealand
- Prior art keywords
- acoustic dampener
- acoustic
- batten
- base member
- base
- Prior art date
Links
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- 238000000034 method Methods 0.000 claims abstract description 13
- 238000009408 flooring Methods 0.000 claims description 47
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- 239000006260 foam Substances 0.000 claims description 15
- 239000011518 fibre cement Substances 0.000 claims description 9
- 229920000642 polymer Polymers 0.000 claims description 9
- 238000001125 extrusion Methods 0.000 claims description 7
- 229920000098 polyolefin Polymers 0.000 claims description 6
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- 238000009434 installation Methods 0.000 abstract description 10
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- 238000009435 building construction Methods 0.000 description 3
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- 208000002153 familial abdominal 3 aortic aneurysm Diseases 0.000 description 1
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Classifications
-
- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04F—FINISHING WORK ON BUILDINGS, e.g. STAIRS, FLOORS
- E04F15/00—Flooring
- E04F15/18—Separately-laid insulating layers; Other additional insulating measures; Floating floors
- E04F15/20—Separately-laid insulating layers; Other additional insulating measures; Floating floors for sound insulation
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
- Y10T29/00—Metal working
- Y10T29/49—Method of mechanical manufacture
- Y10T29/4957—Sound device making
Abstract
acoustic dampener (200) for a floor structure is disclosed. The acoustic dampener (200) comprises a base member (201) having a first surface and a second surface (203). The first surface and the second surface (203) are spaced apart from each other defining a thickness (204) therebetween. The acoustic dampener (200) further comprises a pair of side arms (205), each having a first end and a second end. Each side arm (205) is attached to the base member (201) at its first end at a predetermined angle, where the predetermined angle is elastically deformable to allow for installation of a batten. The side arm (205) extends from the base member to form a channel formation to receive the batten. A flange (206) extends substantially orthogonally from the second end of each side arm (205) for retaining the batten within the channel formation. A floor structure comprising the acoustic dampener and a method of installing a floor structure is also disclosed. ustic dampener (200) further comprises a pair of side arms (205), each having a first end and a second end. Each side arm (205) is attached to the base member (201) at its first end at a predetermined angle, where the predetermined angle is elastically deformable to allow for installation of a batten. The side arm (205) extends from the base member to form a channel formation to receive the batten. A flange (206) extends substantially orthogonally from the second end of each side arm (205) for retaining the batten within the channel formation. A floor structure comprising the acoustic dampener and a method of installing a floor structure is also disclosed.
Description
ACOUSTIC DAMPENER
FIELD OF THE INVENTION
The present invention relates to dampening of acoustic energy and in particular to
acoustic dampeners suitable for use in dampening of acoustic energy transmissions in
buildings.
The invention has been developed primarily for use as acoustic dampeners suitable
for use in acoustic dampening of flooring systems in buildings and will be described hereinafter
with reference to this application. However, it will be appreciated that the invention is not
limited to this particular field of use.
BACKGROUND OF THE INVENTION
Any discussion of the prior art throughout the specification should in no way be
considered as an admission that such prior art is widely known or forms part of the common
general knowledge in the field.
[0004] Strip form acoustic insulation for use between sheet building products and a
structural building substructure, such as timber joists on a frame, are known. They are
generally arranged between a flooring sheet and a flooring substructure and the flooring sheet
is directly fixed to the flooring substructure through the insulating strip. Although some
reduction in sound transmission may occur, it is limited because of the direct connection of the
flooring sheets to the flooring substructure.
Insulating systems, for providing dampening of acoustic transmission, including
multiple layers of sheet material with graded properties, are known. These multiple layer
systems, such as those employing two or more layers of paper faced gypsum boards, increase
the cost of a flooring system both by increasing the amount of materials used for a given floor
area and by requiring additional labour time for installation.
OBJECT OF THE INVENTION
It is an object of the present invention to overcome or ameliorate at least one of the
disadvantages of the prior art, or to provide a useful alternative.
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It is an object of the invention in a preferred form to provide an acoustic dampener
suitable for use in buildings, for decoupling contact between all hard surface components and
thereby reducing acoustic energy transmission, while maintaining low component cost and low
installation skill level.
SUMMARY OF THE INVENTION
According to the invention there is provided an acoustic dampener comprising:
a base member, wherein the base member comprises a first surface and a second
surface, the first and second surface being spaced apart from each other defining a thickness
therebetween;
at least two side arms, wherein each side arm comprises a first end and a second end,
each side arm extending from the first surface of the base member at a pre-determined angle,
such that there is a channel formed therein whereby each side arm and the base member form
the sides and the base of the channel formation respectively; and
a pair of flanges, each flange extending substantially orthogonally from the second end
of each side arm in a plane substantially parallel to the first surface of said base member
wherein the at least two side arms and the pair of flanges are configured to retain a batten
within the channel and wherein the predetermined angle is elastically deformable; and
wherein the first surface further comprises at least one recess for receiving a
mechanical fastener.
The advantage of the present invention is that it provides an acoustic dampener for
use in building construction, which removes or decouples contact between flooring sheet
components and substructure components thereby reducing acoustic energy transmission,
while maintaining low component cost and low installation skill level.
[0010] In the following the description the first and second ends of each side arm are also
referred to as the distal edge and proximal edge of each side arm, wherein each side arm
extends from the proximal edge at the predetermined angle from the side edge of the base to
form the channel formation. Each flange within the pair or flanges extend substantially
orthogonally from respective distal edges of the side arms.
[0011] It is acknowledged that the term „comprise‟ may, under varying jurisdictions be
provided with either an exclusive or inclusive meaning. For the purpose of this specification,
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the term comprise shall have an inclusive meaning that it should be taken to mean
an inclusion of not only the listed components it directly references, but also other non-
specified components.
Accordingly, the term „comprise‟ is to be attributed with as broad an interpretation as possible
within any given jurisdiction and this rationale should also be used when the terms „comprised‟
and/or „comprising‟ are used.
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In one embodiment of the invention the channel formation is configured to receive a
batten.
In a further embodiment of the invention the or each flange is configured to retain a
batten within the channel.
[0015] According to the invention there is also provided a floor structure comprising an
acoustic dampener of the invention securable to a structural substrate, a batten disposed
within the channel formation and flooring material secured to the batten.
In one embodiment of the invention the first end of each of the at least one of the pair
of side arms are pivotably connected to the base member. In a further embodiment of the
invention, at least one of the two side arms is pivotably connected to the base at the junction
between the first surface of the base and the first end of the side arm.
In one embodiment of the invention at least one of the pair of flanges is pivotably
connected to the pair of side arms. In a further embodiment of the invention, at least one of
the pair of flanges is pivotably connected to the side arm at the junction between the flange
and the second end of the aside arm.
In a further embodiment of the invention, the junction between the side arms and the
base, is elastically deformable thus allowing the predetermined angle, α to alter radically during
insertion and removal of the batten into the channel formation and also providing tolerance to
the position of the side arm prior to and during use of the acoustic dampener. In one
embodiment of the invention the pre-determined angle α, falls within a range of 80 to 90
degrees.
In a further embodiment of the invention, wherein the base member further
comprises at least one aperture contained within the thickness of the base member. In a
further embodiment of the invention the at least one aperture extends through the second face
of the base member to form at least one recessed channel on the second face of the base
member. In a further embodiment of the invention the first face of the base member further
comprises at least one profiled portion.
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The advantage of this is that the at least one aperture forms an internal void or space
within the base of the invention, therefore it reduces the volume of material required to form
the base.
In a further embodiment of the invention, the base of the acoustic dampener
comprises dimensions of between approximately 50 to 100 mm wide, preferably between
approximately 60 to 80 mm wide, and most preferably between approximately 75 to 80 mm
wide. In a further embodiment of the invention the height of acoustic dampener is between
approximately 20 to 80mm, preferably between approximately 25 to 50mm, and most
preferably between approximately 30 to 35mm. In a further embodiment of the invention the
thickness of the base is between approximately 10 to 15 mm, preferably is approximately
12mm thick. In one embodiment, base 101 are approximately 10 to 15mm thick, more. In
another embodiment, base 101 is approximately 12mm thick.
In a further embodiment of the invention, each side arm is approximately 10 to 70mm
in height, preferably approximately 15 to 40mm in height, most preferably approximately 20 to
25mm.
In one embodiment of the invention, the predetermined angle α, is angled at
approximately 85 degrees between the side arm and the base, and each side arm is
approximately 5mm thick at its first or proximal end and approximately 3mm thick at its second
or distal end.
[0024] In a further embodiment of the invention, each of the pair of flanges is approximately
to 15mm wide, and each may be approximately 1.5mm thick.
In a further embodiment of the invention the or each aperture may be approximately
5mm in diameter where enclosed channels are used, or 5mm in maximum width in
embodiments where a complex shape aperture is used. Conveniently the apertures are
arranged in a preselected pattern within the thickness of the base.
In a further embodiment of the invention, the base further comprises a recessed
channel. In a further embodiment of the invention, the at least one aperture formed in the base
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of the invention extends through the second face of the base to form at least one recessed
channel.
In a further embodiment of the invention, the first surface of the base further
comprises at least one profiled portion for reducing contact area with a batten.
[0028] In a further embodiment of the invention, the base of the acoustic dampener is
formed from at least one resilient polymer, selected form the group comprising a closed cell
foam, a closed cell linear foam, a closed cell non-linear foam, or a polyolefin foam. It is to be
understood that any suitable polymer known to a person skilled in the art which will achieve the
functionality of the invention can also be used.
[0029] In a further embodiment of the invention, the components of the acoustic dampener
are integrally formed together to form a single unit. In this embodiment of the invention the
base, the side arms and the flange are integrally formed together as a single unit.
In a further embodiment of the invention, the acoustic dampener is formed by an
extrusion process or a co-extrusion process.
[0031] In a further embodiment of the invention, the base comprises at least two portions
formed of materials having different acoustic dampening properties.
In a further embodiment of the invention, the batten is a fibre cement batten.
In a further embodiment of the invention, the flooring material is a fibre cement
flooring material.
[0034] According to the invention, there is also provided a method of installing a floor
structure, including the steps of:
(a) selecting and/or preparing one or more lengths of acoustic dampener in accordance
with the invention;
(b) fixing each length of acoustic dampener in a predetermined position on a structural
flooring substrate to form an acoustic dampener array,
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(c) elastically deforming at least one side arm on each length of acoustic dampener
array and inserting batten sections into each length of acoustic dampener to
substantially fill the “U” shaped channel to form a batten array,
(d) allowing the side arm on each length of acoustic dampener to return to its
substantially original position, and
(e) fixing at least one flooring sheet to each batten section, wherein only the acoustic
dampener array is directly fixed to the flooring structural substrate and each flooring
section is directly fixed only to at least one batten section in the batten array
[0035] From the foregoing, it will be appreciated that certain embodiments of the preferred
embodiments provide a method of installing an acoustic dampened building section. In
particular, certain embodiments of the method are designed to form a building section having
less acoustic transmission than a similar building section constructed without the acoustic
dampener. These and other objects and advantages of the preferred embodiments of the
present invention will become apparent from the following description taken in conjunction with
the following drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention will now be described more particularly with reference to the
accompanying drawings, which show by way of example only various embodiments of the
façade system of the invention.
In the drawings;
Figures 1 (a) and 1 (b) are a cross-sectional view and a perspective view of an
acoustic dampener according to a first embodiment of the invention;
Figure 2 is a cross sectional view of an acoustic dampener according to a second
embodiment of the invention;
Figure 3 is a cross-sectional view of an acoustic dampener according to a third
embodiment of the invention;
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Figure 4 is a cross sectional view of an acoustic dampener according to a fourth
embodiment of the invention;
Figure 5 is a cross-sectional view of an acoustic dampener according to a fifth
embodiment of the invention;
[0043] Figures 6 (a), 6 (b) and 6 (c) are cross-sectional views of the acoustic dampener of
Figure 2 in an installed position; of the acoustic dampener in an installed position with a batten
being installed; and a floor section comprising the batten and the acoustic dampener according
to the invention; and
Figures 7 (a), 7 (b) and 7 (c) are cross-sectional views of the acoustic dampener of
Figure 5 in an installed position; of the acoustic dampener in an installed position with a batten
being installed; and a floor section comprising the batten and the acoustic dampener according
to the invention;
PREFERRED EMBODIMENT OF THE INVENTION
Reference will now be made to the drawings, wherein like numerals refer to like
elements throughout. The drawing figures are not necessarily to scale and certain features
may be shown exaggerated in scale or in somewhat generalized or schematic form in the
interest of clarity and conciseness.
Referring now to Figures 1(a) and 1(b), there is shown an acoustic dampener 100
according to one embodiment of the invention. Acoustic dampener 100 comprises a base 101
including a first surface 102 and a second surface 103 which are spaced apart from each other
defining thickness 104 therebetween. There is at least one aperture 107 formed in the
thickness. The acoustic dampener 100 further comprises a pair of side edges 108 and side
arms 105, each having a first end or distal edge 110 and a second end or proximal edge 109.
Side arms 105 are each conjoined to the base 101 at the first or proximal edge to form a
substantially “U” shaped channel 130 adapted to receive a batten 124. The angle α, between
each side arm 105 and the base 101 is predetermined to accommodate a batten within the
substantially „U‟ shaped channel 130. The acoustic dampener 100 also comprises a pair of
flanges 106, each of which extends substantially orthogonally from a respective second end or
distal edge 110 of each side arm 105 within the pair of side arms 105. The junction between
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the side arms 105 and the base 101, is elastically deformable thus allowing the predetermined
angle, α to alter radically during insertion and removal of a batten and also providing tolerance
to the position of the side arm prior to and during use of the acoustic dampener 100.
In this embodiment of the invention, base 101, pair of side arms 105 and pair of
flanges 106 are integrally formed by extrusion of a resilient closed cell foamed polyolefin
polymer. Other polymers and manufacturing processes may be used. Examples of polymers
that could be used include Natural Rubber, Ethylene Propylene Rubber (EPM), Ethylene
Propylene Diene Rubber (EPDM), Nitrile Rubber, Neoprene Rubber, Thermoplastic
Elastomers (TPE), Silicone Rubber, Polyurethane Rubber, and the like. The polymer is
selected for its capacity to reduce or impede acoustic transmission from a flooring surface
through a flooring support batten and subsequently through a flooring structural substrate with
which it is in contact. Such a polymer may optionally be foamed and may be a closed cell or
an open cell foam. Such commercially available foams may be linear or non-linear in nature.
In this embodiment of the invention, the predetermined angle, α is approximately 85
degrees. This enables a resilient fit of a batten (not shown) into the substantially “U” shaped
channel 130 formed by first surface 102 of base 101 and side arms 105. One or both side
arms of the pair of side arms 105 are elastically deformable to allow fitting of a batten into the
“U” shaped channel, either by bending of the side arms 105 or by rotating an elastically
deformable hinge or pivot portion 111 between the side arms and the first surface 102 of the
base 101 to change angle α. By either method, one or both side arms 105 may be elastically
deformed away from their original manufactured position sufficiently to allow insertion of a
batten. Side arms 105, once released, will attempt to return to their original position. The
position of the side edges of the batten within the “U” shaped channel may result in side arms
105 being resiliently biased against the side edges of the batten.
[0049] In a further example of the invention the apertures 107 may be integrally formed into
base 101 during manufacture to reduce the amount of material necessary to form the acoustic
dampener 101. The size, shape and location of apertures 107 are selectable and may be
varied to provide different options selectively tailored for different applications. Apertures 107
may also serve to reduce the contact area between the acoustic dampener 100 and a flooring
substructure. In some embodiments, at least one of the apertures 107 may be a continuous
channel that also opens through second face 103 of base 101.
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The second face 103 of base provides a contact face for the acoustic dampener 100
on a flooring structural substrate (not shown) such as concrete slab and the like.
As shown in Figure 1(b), first face 102 also includes optional visual indicia 118
marked onto, or formed into, the surface, for providing fixing location indicators and the like.
[0052] Each of the flanges 106 of the acoustic dampener 101 are orthogonal to side arms
105 and extend in a plane substantially parallel to the first surface 102 of base 101. In the
embodiment flanges 106 extend towards each other for a predetermined distance thereby
creating a formation adapted to restrain an installed batten in place. Flanges 106 also serve to
provide an additional barrier for direct sound transmission between a walking surface sheet
and a batten through to the underlying structural substrate.
Dimensions of acoustic dampener 100 may be varied by the manufacturer to suit
individual applications. In the embodiment shown, acoustic dampener 100 comprises base
101 having dimensions of between 50 to 100 mm wide. In an alternate embodiment, base 101
may be between 60 to 80 mm wide. In a further embodiment, base 101 is between
approximately 75 to 80 mm wide.
In one embodiment, the total height of acoustic dampener 100 may be approximately
to 80mm. In another embodiment, the total height is approximately 25 to 50mm. In a
preferred embodiment, the total height is approximately 30 to 35mm.
In one embodiment, base 101 are approximately 10 to 15mm thick, more. In another
embodiment, base 101 is approximately 12mm thick.
In one embodiment, side arms 105 are approximately 10 to 70mm in height. In
another embodiment, side arms 105 are approximaely 15 to 40mm in height. In a preferred
embodiment, side arms 105 are approximately 20 to 25mm. In one embodiment, each of the
pair of side arms 105 is angled at approximately 85 degrees to first face 102, and each is
approximately 5mm thick at its first or proximal end and approximately 3mm thick at its second
or distal end.
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In one embodiment, each of the pair of flanges 106 may be 10 to 15mm wide, and
each may be approximately 1.5mm thick.
Each aperture may be approximately 5mm in diameter where enclosed channels are
used, or 5mm in maximum width in embodiments where a complex shape aperture is used.
Apertures 107 are arranged in a preselected pattern within the thickness of the base.
Referring now to Figure 2, there is shown an acoustic dampener 200 comprising a
base 201 including first surface 202 and second surface 203 defining thickness 204
therebetween. First surface 202 includes at least one profiled portion 221 for minimising the
contact area of first face 202 and a batten installed into the substantially “U” shaped channel
230. In this embodiment, profiled portion 221 is in the form of a series of parallel elongate
protrusions approximately 1mm in height and each approximately 1mm in width. The surface of
each protrusion is profiled, either pointed or rounded or the like, to reduce contact area with a
batten surface. First surface 202 also includes and at least one recess 214 for receiving a
mechanical fastener such that, once installed, the head of the mechanical fastener sits within
the recess and sits below the level of profiled portions 221, thereby preventing contact of the
fastener head with an installed batten, creating non-contact zone 228 and preventing a direct
path for transmission of acoustic energy from the batten to the building substrate.
Recess 214 may also comprise one or more visual indicia 218 for indicating fixing
location points, or may provide an additional location at which the acoustic dampener is
elastically deformable.
Apertures 207 formed within thickness 204 allow for an interruption in the possible
paths for direct transmission of acoustic energy from a batten through the acoustic dampener
to a structural building substrate.
Side arms 205 and flanges 206 function as described for the embodiment of the
invention described above in Figure 1.
Referring now to Figure 3, there is shown a further embodiment of the acoustic
dampener 300 of the invention including base 301 comprising first face 302 and second face
303 spaced apart to define thickness 304 therebetween. As described above, side arms 305
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extend at a predetermined angle α from base 301. Flanges 306 each extend orthogonally from
respective distal edges 310 of side arms 305. In this embodiment of the invention, at least one
of the pair of side arms 305 is connected to base 301 at its proximal end 310 by elastically
deformable hinge or pivot portion 311.
[0064] The mechanical strength of the connection of at least one of the pair of flanges 306
to a respective distal edge 310 of respective side arm 305 may be strengthened by including
reinforcing portion 313. In this embodiment of the invention, arm 305 is elastically deformable
by relative rotation of elastically deformable hinge portion 311.
Elastically deformable hinge portion 311 in this embodiment is integrally formed with
base 301 and side arms 305 and is radiused to provide a portion having a reduced wall
thickness relative to side arm 305.
A fourth embodiment of the invention is shown in Figure 4, which provides an
acoustic dampener 400 including base 401 comprising first face 402 and second face 403
spaced apart to define thickness 404 therebetween. First face 402 includes at least one
profiled portion 421 for minimising contact, when in use, between first face 402 and an
installed batten (not shown).
First face 402 also includes at least one recess 414 with side portions 415 for
providing tapering transition zone and a support zone. First recess 414 in first face 402
optionally includes visual indicia 418 such as for indicating fixing locations. In this embodiment,
visual indicia 418 is in the form of a small recessed channel in the centre of first recess 414.
Recess 414 also reduces the amount of material a mechanical fixing has to penetrate during
installation and increases the ease of installation.
Figure 4 also shows one embodiment of acoustic dampener 400, where a co-
extrusion process is used to integrally form base 401 from two resilient polymeric materials,
each having different acoustic dampening properties. The materials may also have differing
mechanical properties such as hardness or strength. In this figure, base 401 includes at least
one portion 416 of a first material and at least one portion 417 of at least a second material.
In alternate embodiments, portion 416 and portion 417 may be formed from the same material,
but in different physical form, thereby providing portions each having different physical
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properties, such as a non-foamed and a foamed polyolefin. For example, portion 417 may be
formed from a nonlinear polyolefin foam and portions 416, 405 and 406 formed from a linear
polyolefin foam showing different acoustic response characteristics.
Base 401 also includes 3 recess 422 formed in second face 403. Adjacent at least
one edge of 3 recess 422 is support portion 423 for providing mechanical support around
fixing points. Fixing points may be indicated by visual indicia 418 created by 2 recess 419 in
first surface 402. In this embodiment of the invention, apertures 407 are in the form of
channels extending from the interior of thickness 404 to second face 403 of base 401.
Figure 5 shows one embodiment of the invention where acoustic dampener 500 is
integrally formed of a single synthetic rubber material. The acoustic dampener is extruded as
one or more convenient to handle lengths. Examples of convenient to handle lengths may be
3 metres, 5 metres, 10 metres or more. Acoustic dampener 500 may be supplied flat or rolled.
Of course other convenient lengths may be similarly manufactured.
Base 501comprises first surface 502 and second surface 503 defining a thickness
504 therebetween. First surface 502 comprises two profiled portions 521 disposed either side
of first recess 514. Profiled portions 521 are in the form of a series of parallel ridges formed
into the surface of first surface 502. The ridges are approximately 1mm in height and
approximately 1 mm diameter and spaced approximately 1mm apart.
Side arms 505 are 5mm thick at their proximal ends and 3mm thick at their distal
ends. Side arms 505 are 20mm long. Flanges 506 are 3mm thick and 16mm wide. Angle α
between side arms 505 and base 501 is 85 degrees.
Base 501 has apertures 507 in the form of channels formed in thickness 504 and
extending through second surface 503. The apertures are approximately 5mm in width and
approximately 7.5mm deep, terminating as radiused arch formations within thickness 504. A
number of apertures 507 are disposed evenly distributed across the width of base 501.
First surface 502 further comprises first recess 514 in the form of a recessed channel
with tapered side edges transitioning from first surface 502 to the land of the recess for
providing fixing locations for fixing the acoustic dampener to a building structural substrate
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such as a timber flooring frame. Visual indicia 518 in the form of a 1mm deep and 1mm
diameter central channel located in the land of first recess 414 provides a visual guide to fixing
locations, while simultaneously slightly reducing the thickness of material that a mechanical
fixing such as a screw has to penetrate before contacting the substrate.
[0075] Installation of an acoustic dampener according to one embodiment of the invention is
shown in Figure 6 in which Figure 6(a) shows acoustic dampener 600 positioned in a user
selectable position on the surface of a building structural substrate 620 in the form of a
concrete slab. Other building structural substrate materials such as a plywood, MDF, OSB or
other flooring substrate materials may also be appropriate. Acoustic dampener 600 is fixed in
position by mechanical fastener 625, in this embodiment; mechanical fastener 625 is a screw
suitable for use on masonry. Fastener 625 is driven into first recess 614 in first surface 602,
through thickness 604, exiting through second surface 603 and fastening to structural building
substrate 620. Apertures 607 are not deformed during the installation process and provide
maximum disruption to sound transmission. Acoustic dampener 600 may be in the form of an
extruded section of predetermined length or may be in the form of a roll of sufficient length to
cover the length or width of a building or room floor surface, in which case, it may be cut to the
required length by the installer.
Figure 6(b) shows installation of batten 624 by elastically deforming at least one of
the pair of side arms 605 by bending outwards, increasing the angle between side arm 605
and first face 602 and inserting batten 624 into channel 619. Once batten 624 is in position,
each of the elastically deformed side arms 605 is allowed to return substantially to its original
position, leaving a small degree of elastic deformation which provides a resilient bias of side
arms 605 against batten 624 to assist in securing batten 624 in position. Flanges 606 retain
the batten in position within channel 619.
[0077] Once batten 624 is in position, flooring material 626, in the form of a fibre cement
flooring sheet in this embodiment, can be fixed to batten 624 by mechanical fastener 629, as
shown in Figure 6(c). Flooring material 626 remains substantially isolated from direct contact
with batten 624 by pair of flanges 606. Flooring material 626 also remains isolated from direct
contact with structural building substrate 620.
PA1071WO
Direct transmission of acoustic energy from flooring materials 626 to structural
building substrate 620 is reduced or substantially eliminated by combined action of acoustic
dampening properties of the resilient polymer selected; by selected profiling of the acoustic
dampener to minimise contact area between the first face and the batten; by incorporation of
acoustic transmission disrupting apertures in the thickness of the acoustic dampener; by
optional reduction in the contact area between batten 624 and building structural substrate
620; by providing a spacer between the flooring material 626 and batten 624 via flanges 605;
by eliminating any direct hard surface contact of flooring material 513 with building structural
substrate 620; and by eliminating direct contact between mechanical fastener 625 and batten
624. Airborne transmission is also reduced by dampening transmission into airspace within
the floor structure, from battens 624, by side arms 605.
Examples of acoustic dampeners according to embodiments of the invention are
provided below.
EXAMPLE ONE;
[0080] This example demonstrates the improvement in acoustic performance achievable
using acoustic dampeners according to one embodiment of the invention. In this example, a
timber structural substrate, in the form of a flooring subframe, is constructed in the normal way
with 100 x 75mm bearers supporting 100 x 50mm joists spaced at 600 mm centres. This
timber structural substrate forms the base of the flooring system in a building construction.
[0081] In this example, acoustic dampeners of the invention are in the form of extruded
sections 3 metres in length. Each acoustic dampener is made from an EPDM rubber having a
Shore hardness of 45-50. The acoustic dampener has a base 76mm wide at its widest point,
with the lower corners radiused at a 2mm radius. The second surface of the base has a series
of recessed channels 5mm wide, 6mm deep and evenly spaced 5mm apart across the second
surface. Each channel termination within the thickness is radiused at about a 2.5mm radius. A
centre support portion of the lower face of the base does not include any recessed channels, in
order to provide additional support around the screw fixing locations. This centre portion is
12mm wide.
PA1071WO
The acoustic dampener base is 12mm thick at its thickest point. On the first surface
of the base, a series of parallel channels 1mm deep are formed to reduce the direct contact
area between the lower surface of a batten and the first surface of the acoustic dampener. A
first recess 12mm wide, located centrally in the first face of the base and recessed by 3mm into
the base, provides a convenient location for screw fixing the acoustic dampener to the
subfloor, in this case to a joist. The screw head, when tightened down, sits within the first
recess and sits below the plane of contact between the first surface of the acoustic dampener
base and the lower surface of an installed batten, leaving a non-contact zone between the
fastener head and the batten, thereby preventing direct contact and any direct pathway for
sound transmission.
At each side edge of the base, a side arm 3mm thick protrudes almost orthogonally
at an angle of 85 degrees to the upper face of the base, angled towards the centre of the base.
Each side arm is 22mm in length from the top surface of the base. At the end of each side
arm, a flange 1.5mm thick extends parallel to the upper surface of the base, towards the
centre.
Acoustic dampeners are fixed to the joists, in this example, at a spacing of 600mm
Each acoustic dampener is fixed to the joist using screws. Fixing points may optionally be
indicated on the surface of the acoustic dampener by printed marks, embossed marks, and the
like. Once the acoustic dampeners are fixed in place, timber battens 70mm wide and 19mm
thick are inserted into each acoustic dampener by elastically deforming one or both side arms
of the acoustic dampener to allow full insertion of a batten into an acoustic dampener.
Once the timber batten is in place, a walking surface is positioned over the battens
and is fixed to the battens at manufacturer recommended spacings. The underside of the
walking surface contacts the flanges of the acoustic dampener and direct contact between the
walking surface and the batten is prevented.
In this embodiment, the walking surface comprises 22 mm thick fibre cement flooring
sheets installed according to the manufacturers recommendations. In this example, a
lightweight nailable structural flooring product Secura™ Interior Flooring manufactured by
James Hardie Australia Pty Ltd was used. Secura™ Interior Flooring may be nail fixed to a
substrate, other flooring materials such as compressed fibre cement sheet may need to have
PA1071WO
holes pre-drilled at recommended fixing spacings before the flooring sheets are screw fixed to
the battens.
RESULTS
[0087] Results of acoustic testing are provided below in Table 1.
TABLE 1
Walking Surface Joist Spacing Acoustic Airborne Impact
thickness (mm) (mm) dampener used? Rw +Ctr Lnw
22 600 No 52 67
22 600 Yes 57 55
EXAMPLE 2
[0088] In this embodiment of the invention, a timber subframe is constructed in the normal
way using 100 x 75mm timber bearers and 100 x 50mm joists at 600 mm centres.
Acoustic dampeners are screw fixed to the joists. In this example, each acoustic
dampener is formed from an EPDM rubber having a Shore hardness of 50-55.
In this example, each acoustic dampener is in the form of an extruded section 10
metres in length and supplied in roll form that can be cut to the required lengths. Where there
is a section too short to fit the desired location, another length can be cut from another roll to
make up the difference. The leading end of the new length can be butted up against the trailing
end of the preceding length to ensure continuity of performance along the length of the joist.
The acoustic dampener has a base 77mm wide at its widest point, with the lower
corners radiused at a 2mm radius. The thickness of the base has a series of 6 circular cross-
section apertures each 5mm diameter spaced 10mm apart, in two groups of three distributed
symmetrically either side of the first recess in the first face. The centre of each aperture is
approximately 6mm from the second surface of the base and each aperture extends
substantially parallel to the second face, through the length of each acoustic dampener.
[0092] The acoustic dampener base is 12mm thick at its thickest point. On the first surface
of the base, a series of parallel channels 1mm deep are formed to reduce the contact area
PA1071WO
between the lower surface of a batten and the first surface of the acoustic dampener. A first
recess 16mm wide, located centrally in the first face of the base and recessed by 3mm into the
base, provides a convenient location for screw fixing the acoustic dampener to the subfloor, in
this case to a joist. The screw head, when tightened down, sits within the first recess and sits
below the plane of contact between the first surface of the acoustic dampener base and the
lower surface of an installed batten, leaving a non-contact zone between the fastener head
and the batten, thereby preventing direct contact and any direct pathway for sound
transmission.
At each side edge of the base, a side arm 3mm thick protrudes almost orthogonally
at an acute angle of 85 degrees to the first face of the base, angled towards the centre
longitudinal axis of the base. Each side arm is approximately 21mm in length from the first
surface of the base. At the end of each side arm, a flange 1.2mm thick and 12mm long
extends parallel to the first surface of the base, towards the central longitudinal axis. At the
distal ends of the side arms, the acoustic dampener is 71mm in width. A side arm thickness of
3mm each makes the width of the channel into which the batten is fitted, about 65mm.
Acoustic dampeners are fixed to the joists, in this example, at a spacing of 600mm.
Each acoustic dampener is fixed to the joist using timber screws. Fixing points may optionally
be indicated on the surface of the acoustic dampener by printed marks, embossed marks, and
the like. In this example, visual inidica indicating fixing locations is in the form of a 2 recess
in first surface of the base. The 2 recess is 0.5mm wide and 0.5mm deep and is located in
the centre of the first recess and extends along the length of the acoustic dampener.
Once the acoustic dampeners are fixed in place, timber battens 70mm wide and
19mm thick are inserted into each acoustic dampener by elastically deforming the acute angle
of one or both side arms of the acoustic dampener to allow full insertion of a batten into an
acoustic dampener. Once in position, the side arms are allowed to relax and return as much as
possible to their original position. The width of the batten at 70mm means that the distal ends
of each side arm is slightly elastically deformed from its original position, and is resiliently
biased against the side of the batten, thereby assisting in retaining the batten securely in place
and with little or no ability to move out of position.
PA1071WO
Once the timber batten is in place, a walking surface is positioned over the battens
and is fixed to the battens at manufacturer recommended spacings. The underside of the
walking surface contacts the flanges of the acoustic dampener and direct contact between the
walking surface and the batten is prevented.
[0097] In this embodiment, the walking surface comprises 22 mm thick fibre cement flooring
sheets installed according to the manufacturers recommendations. In this example, a
lightweight nailable structural flooring product, Secura™ Interior Flooring manufactured by
James Hardie Australia Pty Ltd was used. Secura™ Interior Flooring may be nail fixed to a
substrate, other flooring materials such as compressed fibre cement sheet may need to have
holes pre-drilled at recommended fixing spacings before the flooring sheets are screw fixed to
the battens.
RESULTS
Results are given in Table 2 below.
TABLE 2
Walking Surface Joist Spacing Acoustic Airborne Impact
thickness (mm) (mm) dampener used? Rw +Ctr Lnw
22 600 No 52 67
22 600 Yes 58 54
It will be appreciated that the illustrated acoustic dampener provides an acoustic
dampener for use in building construction, for decoupling contact between all hard surface
components and thereby reducing acoustic energy transmission, while maintaining low
component cost and low installation skill level.
[00100] The acoustic performance of all examples provided above meets or exceeds the UK
Building Code ADE AAA3 (Resistance to the Passage of Sound) provisions for an L‟
nT,w
maximum value of 64 dB for floors, and stairs in buildings. (The lower the value the better).
The L‟ value is the impact sound pressure level in a stated frequency band, corrected for
nT,w
reverberation time, according to BS EN ISO 140-7:1998.
[00101] The D + C standards for airborne noise transmission between rooms are also
nT,w tr
met or exceeded by all examples provided above. The D + C minimum value under the
nT,w tr
code is 43dB. D is a measure of the difference in sound pressure level in dB between a
nT,w
PA1071WO
room in which the sound/noise is generated and an adjacent “receiving room”, at a prescribed
reverberation time. In simple comparison terms, the higher the value of D , the better the
nT,w
acoustic performance of the material/construction is. The larger the number, the larger is the
difference in sound pressure level discernible in the two spaces, and therefore, the more
effective is any acoustic dampener used in the test structure. C is a correction factor used in
conjunction with D to allow for low frequency bass sounds in airborne transmission.
nT,w
Sound pressure levels are typically reported in decibel (dB) units. With 0dB
representing the threshold of audibility for a person of normal hearing capacity and 100dB
representing, say, the noise level in a subway railway station or heavy industrial machinery in
operation. In a normal daily urban environment, a person may be exposed to sound levels
such as average street noise at around 70dB, an average office environment at around 60dB,
an average conversation at around 50dB, and a quiet or private office at around 40dB. The
correlation between sound intensity and sound pressure is logarithmic and an increase of
10dB in sound pressure level represents a 10-fold increase in sound intensity level, so the
sound intensity at 100dB is 10,000,000,000 times greater than that at 0dB. For a person of
normal hearing, a change of 1-2dB is not detectable. A change of 5dB, however, is clearly
detectable and a change of 10dB is regarded as either a halving (if reduced by 10dB) or
doubling (if increased by 10dB) of the noise level. A relatively small change in dB sound levels
may, in fact, represent a significant change in the sound intensity in a environment.
[00103] Many sounds that people are exposed to in a modern environment span across a
range of frequencies from about 50 Hz up to about 10kHz. Voices are predominantly in the
100-300 Hz range. Heavy vehicles may be in the 50-1000 Hz range and car horns are in the
AAA-5000 Hz range. All of the sounds in an environment may reach a person at different
sound intensity depending on how far away they are from the source, any material between
the person and the source of the sound that may act to absorb or transmit those sounds, and
the sound travel pathways available.
Each material will have a characteristic sound absorption/transmission effectiveness
depending not only its inherent material properties, but also its physical configuration such as
shape, thickness and the like. Sound may also be transferred either directly through the
material of a building section such as a wall or floor section &/or indirectly through airborne
transmission.
PA1071WO
Creating an environment for people, such as in residential dwellings or
office/commercial spaces, requires that noise or sound intensity levels are managed. The ideal
is to create an environment where sound intensity, through both direct and indirect
transmission pathways, is below nuisance levels both for the person themselves and for any
immediately adjacent neighbours.
It will of course be understood that the invention is not limited to the specific details
described herein, which are given by way of example only, and that various modifications and
alterations are possible within the scope of the invention as defined in the appended claims.
PA1071WO
Claims (19)
1. An acoustic dampener comprising: a base member, wherein the base member comprises a first surface and a second surface, the first and second surface being spaced apart from each other defining a thickness 5 therebetween; at least two side arms, wherein each side arm comprises a first end and a second end, each side arm extending from the first surface of the base member at a pre-determined angle, such that there is a channel formed therein whereby each side arm and the base member form the sides and the base of the channel formation respectively; and 10 a pair of flanges, each flange extending substantially orthogonally from the second end of each side arm in a plane substantially parallel to the first surface of said base member wherein the at least two side arms and the pair of flanges are configured to retain a batten within the channel and wherein the predetermined angle is elastically deformable; and wherein the first surface further comprises at least one recess for receiving a 15 mechanical fastener.
2. An acoustic dampener according to Claim 1, wherein at least one of the pair of side arms is pivotably connected to the base member.
3. An acoustic dampener according to Claim 1 or Claim 2, wherein at least one of the pair 20 of flanges is pivotably connected to a respective second end of one of the pair of side arms.
4. An acoustic dampener according to any one of the preceding claims, wherein the base member further comprises at least one aperture contained within the thickness of the base member.
5. An acoustic dampener according to Claim 4, wherein the at least one aperture extends 25 through the second face of the base member to form at least one recessed channel.
6. An acoustic dampener according to any one of the preceding claims, wherein the first face further comprises at least one profiled portion.
7. An acoustic dampener according to to any one of the preceding claims, wherein the base member comprises at least one resilient polymer material. PA1071WO
8. An acoustic dampener according to Claim 7, wherein the at least one resilient polymer is a closed cell foam.
9. An acoustic dampener according to Claim 8, wherein the closed cell foam is a closed cell linear foam. 5
10. An acoustic dampener according to Claim 8, wherein the closed cell foam is a closed cell non-linear foam.
11. An acoustic dampener according to any one of Claims 8 to 10, wherein the resilient foam is a polyolefin foam.
12. An acoustic dampener according to any one of the preceding claims, wherein the base 10 member, at least two side arms and the pair of flanges are integrally formed together.
13. An acoustic dampener according to any one of the preceding claims, wherein the acoustic dampener is formed by an extrusion process.
14. An acoustic dampener according to Claim 13, wherein the extrusion process is a co- extrusion process.
15 15. An acoustic dampener according to Claim 14, wherein the base member comprises at least two portions formed of materials having different acoustic dampening properties.
16. A floor structure comprising an acoustic dampener according to any one of Claims 1 to 15 securable to a structural substrate, a batten disposed within the channel formation and flooring material secured to the batten. 20
17. A floor structure according to Claim 16, wherein the batten is a fibre cement batten.
18. A floor structure according to Claim 16 or Claim 17, wherein the flooring material is a fibre cement flooring material.
19. A method of installing a floor structure, including the steps of: PA1071WO
Applications Claiming Priority (3)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| GB1122133.0 | 2011-12-22 | ||
| GB1122133.0A GB2497805A (en) | 2011-12-22 | 2011-12-22 | An acoustic batten cradle |
| PCT/EP2012/076861 WO2013093109A1 (en) | 2011-12-22 | 2012-12-22 | Acoustic dampener |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| NZ624135A NZ624135A (en) | 2016-01-29 |
| NZ624135B2 true NZ624135B2 (en) | 2016-05-03 |
Family
ID=
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