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Description  |
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BACKGROUND OF THE INVENTION
This invention relates to space dividing wall panels of the open-office
plan type, and more particularly, to a wall panel which can serve both as
a tackable surface as well as a sound absorptive panel.
As use of the open-office plan, employing space dividing wall panels,
becomes more prevalent, it is readily apparent that acoustic performance
of the panels in terms of sound absorption is becoming more important as a
major selling factor as well as an architectural requirement. Integral
bulletin boards or tackable surfaces are also a dominant feature of many
space dividing wall panel systems. Unfortunately, sound absorption
characteristics and the ability to maintain performance as a tackable
surface over long periods of time are concepts which are diametrically
opposed considering the present state of the art. Most available tackable
boards or panels provide the very worst sound absorption characteristics
because the tackable facing is almost always hard and highly reflective to
sound which results in a reflective sound wave almost equally as intense
as the incident sound wave. The soft surface panel which is in much use
today usually employs a fiberglass or similar sound absorbing material
with a cloth covering and is quite unacceptable as a tackable board or
panel because its structural strength and life expectancy are damaged
significantly by the pin portions of the tacks. One attempt to solve this
problem employs sound absorptive material, usually fiberglass, pressed to
a high density and inserted behind the cover cloth. The results are
somewhat satisfactory but the material is more brittle and subject to
surface contact damage, is more expensive to produce, and unsatisfactory
as a sound absorptive medium at the higher frequencies. Accordingly,
providing a combination of good sound absorption performance in a tackable
panel is highly desirable.
SUMMARY OF THE INVENTION
The tackable sound absorptive panel of this invention is substantially
equal in sound absorptive characteristics as conventional sound absorbing
panels while evidencing good structural strength and maintenance even
after numerous tackings thereto by conventional tack pins. The sound
absorptive, tackable, space dividing wall panel of this invention is
adapted to receive tack pins and the like of a predetermined length for
supporting material thereto by including a first planar layer of sound
absorptive material extending over a portion of at least one side of the
space dividing wall panel. A wire mesh screen covers the outwardly facing
surface of the first planar layer of sound absorptive material and a
second planar layer of sound absorptive material covers the outwardly
facing surface of the wire mesh screen, thereby sandwiching the wire mesh
screen between the first and second planar sound absorptive layers. A
cover cloth covers the outer surface of the second sound absorptive layer
with the wire mesh screen being located a distance from the outer surface
of the cloth cover which is less than a tack pin length.
In accordance with the present invention, a rigid frame is provided which
surrounds a rigid central support member dividing the wall panel into two
sides bounded by the frame; a first sound absorptive layer is provided on
each side of the central support member and a wire mesh screen covers the
outer surface of each of the first sound absorptive layers. A second sound
absorptive layer covers the outer surface of each of the wire mesh screens
and a cover cloth covering each of the second sound absorptive layers
forms the outer surface of the sound absorptive tackable wall panel. The
wire mesh screens are located a distance from the outer surface of the
cover cloth so that the tips of the tacks or the like inserted into the
cover cloth extend through the wire mesh screen. A second wire mesh
screen, for additional structural support, can be interposed between the
outer surface of the second sound absorptive layers and the cover cloth
which forms the outer surface of the sound absorptive panel. The second
layer of sound absorptive material can be eliminated and the cloth cover
applied directly to the wire mesh screen if the wire mesh screen has been
coated with a rubber-like substance. Of course, the wire mesh screen need
only be applied to that portion of the panel which is intended to act as a
tackable surface.
BRIEF DESCRIPTION OF THE DRAWING
Many of the attendant advantages of the present invention will become more
readily apparent and better understood as the following detailed
description is considered in connection with the accompanying drawing in
which:
FIG. 1 is a perspective view of a space dividing wall panel constructed in
accordance with the present invention;
FIG. 2 is a partial-sectional view illustrative of a prior art tackable
wall panel;
FIG. 3 is a partial-sectional view illustrative of a prior art acoustical
wall panel;
FIG. 4 is a partial-sectional view of a tackable sound absorptive wall
panel constructed in accordance with the present invention;
FIG. 5 is a partial-sectional view of another embodiment of a tackable
sound absorptive wall panel of this invention;
FIG. 6 is a schematic view illustrating the confinement of a tack pin by
the wire mesh screen of this invention;
FIG. 7 is a partial-sectional view of a still further embodiment of a
tackable sound absorptive wall panel of this invention.
DESCRIPTION OF THE PREFERRED EMBODIMENT
Referring now in detail to the drawings wherein like reference characters
represent like parts throughout the several views, there is illustrated in
FIG. 1 a typical space dividing wall panel of the type employed in the
modern open-office plan systems, modified in accordance with the present
invention. The wall panel is generally of the type disclosed in U.S. Pat.
No. 3,762,116 for "Space Divider System And Connector Assembly Therefor"
which may be utilized in connection with a plurality of cylindrical posts
and other wall panels to provide a plurality of offices in accordance with
the open-office plan concept. Although the panel generally designated 10
is illustrated with connecting hardware which is compatible with the
cylindrical post systems, it should be understood that the connecting
assembly for the panels is not significant with respect to this invention,
and the tackable sound absorptive wall panel of this invention is
applicable to any space dividing wall panel system regardless of the
connecting hardware construction. As illustrated, the space dividing wall
panel generally includes a rectangular structural frame of wood or metal
which may be covered by, as for example, the top cover strip 12 and bottom
cover strip 14, and also covered at its edges by edge cover strips 16
which, as illustrated in FIG. 1, represent steel slotted standards
provided with connector hooks 18 for mounting to a cylindrical post.
Generally, such panels are provided with a rigid central structural member
or septum as illustrated at 20 in each of FIGS. 2 to 5 to which the
remainder of the panel structure is secured in a sandwich type fashion.
Acoustical performance of a space dividing wall panel is becoming more
important and the requirement is essentially defeated where the architects
require the availability of tackable boards or the like in connection with
the open-office plan. As illustrated in FIG. 2, contemporary tackable
surfaces are usually provided by employing mineral board or cork 22 as the
outer surface of the space dividing wall panel. The mineral board or cork
surfaces are exceptionally suitable for receiving tack-type pins 24 with
little destruction from the pin portion 26 thereof through repetitive use.
Repetitive mounting of tackable loads to the tack board surface evidences
no significant damage over the life of the panel. The problem is that the
mineral board or cork tackable surface is probably the worst sound
absorptive material available. The takable facing is essentially a hard
and highly reflective surface to sound waves which results in a reflective
sound almost equal in intensity to the incident sound wave as illustrated
in FIG. 2.
A typical sound absorptive panel is illustrated in FIG. 3 and shows the
septum or center support member 20 surrounded on each side by sound
absorptive material, as for example, pressed fiberglass 28. A cover cloth
30 of, for example, burlap generally forms the outer surface of the space
dividing wall panel. When a sound absorptive space dividing wall panel,
constructed as illustrated in FIG. 3, is utilized as a tackable wall panel
by the insertion of tacks 24 having pin extensions 26, lateral support for
the pin extension 26 is inadequate. The pin portion 26 of the tack will
generally move in response to weight thereon, creating destructive
apertures or tears within the sound absorptive material. Repeated use of
the wall panel as a tackable surface will create a plurality of these
apertures or cavities which is eventually destructive of the panel as well
as providing nonsupportive voids for later tack insertions.
In accordance with the present invention, the sound absorptive material 28
is essentially made in two layers as illustrated at 32, 34 of FIG. 4 and a
wire mesh screen is inserted therebetween over the area to be utilized as
a tackable surface. The wire mesh screen 36 lies in a plane within the
wall panel spaced from the outer surface of the cover cloth 30 a distance
which is slightly less than the length of the pin portion 26 of a
conventional tack pin 24. When the tack pin 24 is inserted, the pin
portion 26 extends through one of the apertures in the wire mesh screen
36, as illustrated in FIG. 6, and prevents lateral movement of the end of
the pin within the sound absorptive material, thus eliminating destruction
of the material and the creation of nonsupportive voids within the sound
absorptive material.
In one alternative embodiment illustrated in FIG. 5, a second wire mesh
screen 38 is sandwiched between the outer surface of the second sound
absorptive layer 34 and the cover cloth 30, thereby providing a pair of
spaced parallel lateral support structures, wire screens 36 and 38, for
the pin portion 26 of the tack pin 24.
In a second alternative embodiment, illustrated in FIG. 7, a single wire
mesh sceen 38 was bonded with a latex adhesive to the outer surface of a
single layer of sound absorptive material and the cover cloth 30 applied
directly to the outer surface of the wire mesh screen. Although tack
support was not quite as good as the two screen embodiment, it was clearly
adequate and construction costs are considerably cheaper.
In accordance with the specific embodiment, the septum or central
structural support member 20 may be constructed from thick pressed paper,
plywood, etc. or some other similar rigid supportive material, such as a
paper honeycomb structure. In a typical panel 11/2" thick, the septum is
generally about 1/8" thick pressed paper. The sound absorptive material is
preferably 6 lbs./ft..sup.3 pressed fiberglass, but any conventional sound
absorptive material may be employed as a substitute for the fiberglass.
The wire mesh screens 36 and 38 are preferably 16.times.18 mesh 32 gauge
aluminum wire screens, but may be any similar wire screen, fiberglass
screen, or polyvinyl chloride screen. Additionally, the screen may be
coated with a rubber-like substance to improve pin retention. A thin
coating of silicone rubber has been proven very successful in this
application. The cover cloth may be any of the conventional cover cloths
employed in sound absorptive panels; and in accordance with the invention
as illustrated is burlap cover cloth.
If desired, the screen may be bonded to the insulating material. In one
method of construction, the substrate, pressed fiberglass, was sprayed
with a latex adhesive, diluted 50% with water, and a polyvinyl chloride
screen pressed onto the tacky pressure sensitive adhesive.
A conventional sound absorptive panel 11/2" thick, consisting of a burlap
cover cloth with two layers of 11/16" thick 6 lbs./ft..sup.3 fiberglass
with a 1/8" pressed paper septum was tested in a 10 cm. diameter impedance
tube for normal sound absorption. This conventional sound absorptive panel
yielded a noise reduction coefficient (NRC.sub.n) rating of 0.6 as
compared to a noise reduction coefficient (NRC.sub.n) of 0.3 for a typical
commercially available tackable panel consisting of burlap cover cloth on
both sides with a mineral board, 1/2" thick tackable surface as
illustrated in FIG. 2.
As an example, the conventional sound aborptive panel evidencing a noise
reduction coefficient (NRC.sub.n) rating of 0.60 was modified in
accordance with the two screen construction of FIG. 5 using both coated
and uncoated screens and the following noise reduction coefficients,
rounded off to the nearest 0.05, for normal incidents were obtained:
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TACKABLE SOUND ABSORPTIVE PANEL
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Uncoated Screens - (NRC.sub.n)
= .66 .65
Coated Screens - (NRC.sub.n)
= .52 .50
Front Screen Coated,
Second Screen Uncoated - (NRC.sub.n)
= .60 .60
Front Screen Coated,
Second Screen Uncoated - (NRC.sub.n)
= .54 .55
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From these tests it can be observed that at worst the (NRC.sub.n) was
reduced from 0.60 to 0.50 and at best it was actually increased to 0.65. A
number of tacks were inserted into the tackable sound absorptive panels
and in all instances the tacks stayed on the panel surface securely and
carried its load without damage to the fiberglass portions of the panel.
As will be apparent from the foregoing, the tackable sound absorptive space
dividing wall panel of this invention provides good acoustical
characteristics in the form of sound absorption while additionally
providing a tackable surface wherein the tacks are retained, do not damage
the panel structure and will have the ability to carry loads on the tack
equal to that of a conventional cork or mineral board tackable surface.
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