The subject invention relates to a compression-cutting assembly for forming one or more longitudinally extending series of cuts and separable connectors in a fibrous insulation blanket so that the insulation blanket can be handled and installed as a unit or separated by hand along a longitudinally extending series of cuts and separable connectors into blanket sections having widths less than the insulation blanket and to a method of using the compression cutting assembly to form the one or more series of cuts and separable connectors in a fibrous insulation blanket. The invention includes the use of a unique compression-cutting blade and anvil assembly and a method of selecting the sizes of the teeth and notches in the compression-cutting blade that includes the use of-an empirical equation.
Fibrous insulation blankets, such as glass fiber insulation blankets in batt or roll form are typically used to insulate the walls, ceiling, floors and roofs of homes and other residential building structures as well as for other similar insulating applications. A pre-cut fibrous insulation blanket and, in particular, a pre-cut resilient glass fiber insulation blanket has recently been developed which contains one or more longitudinally extending series of cuts and separable connectors that enable the insulation blanket to be handled and installed as a unit or separated by hand along a longitudinally extending series of cuts and separable connectors into blanket sections having widths less than the insulation blanket. These pre-cut fibrous insulation blankets enable insulation contractors to size the insulation blankets in width to insulate both standard width and narrower non-standard width building cavities formed by the framework of a building, such as external wall cavities of a residential building that are defined by the studs, without having to cut the insulation blankets in the field. By eliminating the need to cut the insulation blankets in the field, the pre-cut fibrous insulation blankets eliminate a safety hazard associated with the use of knives or other sharp cutting implements to cut insulation blankets in the field, greatly reduce the time required to insulate such cavities, and reduce unwanted scrap.
However, for best results, each series of longitudinally extending cuts and separable connectors formed in the insulation blanket should have separable connectors that have the integrity to hold the blanket sections together for handling and installation as a unit for insulating a standard width cavity while being readily tearable or separable, without the formation of tear outs, to enable the insulation blanket to be separated along one of the longitudinally extending cuts and separable connectors to form insulation blankets of lesser widths for insulating nonstandard width cavities. In addition, for ease of manufacture and for cost savings, the cutting assembly for forming each series of cuts and separable connectors in the fibrous insulation blanket should minimize damage to the separable connectors; not create excessive dust when cutting the fibers during the cutting operation, and minimize wear to the cutting assembly which would cause excessive down time.
The compression-cutting assembly of the subject invention and the method of using the compression-cutting assembly of the subject invention accomplish all of the objectives outlined in the preceding paragraph. The compression-cutting assembly of the subject invention includes a series of spaced apart circular compression-cutting blades and a cooperating moving anvil for forming at least one and, preferably a plurality of, longitudinally extending series of alternating cuts and separable connectors in a fibrous insulation blanket intermediate lateral edges of the fibrous insulation blanket. Each series of alternating cuts and separable connectors in the fibrous insulation blanket form the fibrous insulation blanket into separable blanket sections so that the fibrous insulation blanket can be handled and installed as a unit or easily separated by hand along a longitudinally extending series of alternating cuts and separable connectors into blankets having widths less than the width of the fibrous insulation blanket.
Each circular compression-cutting blade has an outer peripheral edge formed by a series of compression-cutting teeth separated by a series of notches. The lengths of the compression-cutting teeth and notches along the outer peripheral edge of each circular compression-cutting blade are selected to form each series of alternating cuts and separable connectors so that the separable connectors have the integrity to hold the blanket sections together for handling and installation as a unit while enabling the fibrous insulation blanket to be easily separated by hand along any of the series of alternating cuts and separable connectors to form blankets having a lesser width than the fibrous insulation blanket.
The moving anvil surface, along with conveyor belts that feed the fibrous insulation blanket to and remove the fibrous insulation blanket from the compression-cutting assembly, pass the fibrous insulation blanket between the compression-cutting blade(s) and the anvil at a selected velocity. The moving anvil surface not only provides a surface that cooperates with the compression-cutting teeth of the circular compression-cutting blade(s) to crush and cut the fibers of the fibrous insulation blanket, but also, through contact between the compression-cutting blade teeth and the moving anvil surface, drives the compression-cutting blade(s). With the moving anvil surface driving the compression-cutting blade(s) through contact between the compression-cutting blade teeth and the moving anvil surface, the compression-cutting blade(s) are rotated to move the outer peripheral edge(s) of the compression-cutting blade teeth at or substantially at the selected velocity of the moving anvil surface. With the outer peripheral edges of the compression-cutting blade teeth moving at or substantially at the same velocity as the fibrous insulation blanket when forming the one or more longitudinally extending series of alternating cuts and separable connectors in the fibrous insulation blanket, the blanket is not torn by a difference in velocity between the compression-cutting teeth and the fibrous insulation blanket. Preferably, the moving anvil surface that cooperates with the compression-cutting teeth of the compression-cutting blade(s) is the surface of either a cylindrical anvil or a continuous belt anvil.
In a preferred embodiment, each compression-cutting blade has an annular shoulder adjacent the bases of the notches and teeth to reduce the stresses otherwise generated in the separable connectors as a series of alternating cuts and separable connectors is being formed in the fibrous insulation blanket by compressing portions of the fibrous insulation blanket between the compression-cutting teeth and the moving anvil surface. In addition, to facilitate the formation of the cuts in the fibrous insulation blankets by the compression-cutting assembly, a blanket-compressing device can be used to compress the resilient fibrous insulation blankets and temporarily increase their density.
Through the use of an empirical equation, the subject invention also provides a method of selecting the relative sizes of the teeth and notches used in the circular compression-cutting blade(s) of the compression-cutting assembly of the subject invention that greatly simplifies the task of designing the circular compression-cutting blade(s) of the subject invention.
Examples of other fibers that may be used to form the pre-cut fibrous insulation blanket are mineral fibers, such as but not limited to, rock wool fibers, slag fibers, and basalt fibers, and organic fibers such as but not limited to polypropylene, polyester and other polymeric fibers. The fibers in the pre-cut fibrous insulation blanket may be bonded together for increased integrity, e.g. by a binder at their points of intersection such as but not limited to urea phenol formaldehyde or other suitable bonding materials, or the pre-cut fibrous insulation blanket may be binder-less provided the blanket possesses the required integrity and resilience.
Due to its resilience, the preferred pre-cut resilient fibrous insulation blanket 20 can be compressed to reduce the blanket in thickness for packaging. When the pre-cut resilient fibrous insulation blanket is removed from the insulation package, the blanket recovers to substantially its pre-compressed thickness. However, the resilience of the pre-cut resilient fibrous insulation blanket provides another very important benefit. After a full width pre-cut resilient fibrous insulation blanket or a reduced width resilient fibrous insulation blanket formed from the full width pre-cut resilient fibrous insulation blanket is compressed in width and inserted into a cavity having a width somewhat less than the width of the full width pre-cut resilient fibrous insulation blanket or reduced width resilient fibrous insulation blanket, the full width pre-cut resilient fibrous insulation blanket or reduced width resilient fibrous insulation blanket will expand laterally to the width of the cavity and press against the sides of the cavity to hold or help hold the pre-cut resilient fibrous insulation blanket or reduced width resilient fibrous insulation blanket in place.
Preferably, full width pre-cut resilient glass fiber insulation blankets and reduced width glass fiber insulation blankets formed by the compression-cutting assembly and/or method of the subject invention have a density between about 0.3 pcf to about 1.6 pcf; can be compressed laterally up to between 1.0 and 3.0 inches; and will expand laterally to resiliently engage the sidewalls of cavity. The full width pre-cut resilient glass fiber insulation blankets and reduced width resilient glass fiber insulation blankets of the subject invention having a density between about 0.3 pcf to about 1.0 pcf can be compressed laterally between 2.0 and 3.0 inches without appreciably adversely affecting the thermal and/or acoustical performance of the insulation blanket. However, the higher density full width pre-cut resilient glass fiber insulation blankets and reduced width resilient glass fiber insulation blankets of the subject invention having a density between about 1.0 pcf and about 1.6 pcf may exhibit some reduction in thermal and/or acoustical performance when compressed laterally a distance greater than 1 to 2 inches.
While the pre-cut fibrous insulation blankets formed by the compression-cutting assembly and/or method of the subject invention may be in roll form, for most applications, such as the insulation of walls in homes and other residential structures, the pre-cut resilient fibrous insulation blankets are in the form of batts about 46 to about 59 inches in length (typically about 48 inches in length) or 88 to about 117 inches in length (typically about 93 inches in length). Typically, the widths of the pre-cut resilient fibrous insulation blankets are substantially equal to or somewhat greater than standard cavity width of the cavities to be insulated, for example: about 15 to about 15½ inches in width (a nominal width of 15 inches) for a cavity where the center to center spacing of the wall, floor, ceiling or roof framing members is about 16 inches (the cavity having a width of about 14½ inches); and about 23 to about 23½ inches in width (a nominal width of 23 inches) for a cavity where the center to center spacing of the wall, floor, ceiling or roof framing members is about 24 inches (the cavity having a width of about 22½ inches). However, for other applications, the pre-cut resilient fibrous insulation blankets may have different initial widths determined by the standard widths of the cavities to be insulated by the insulation blankets.
The thicknesses of the pre-cut fibrous insulation blankets formed by the compression-cutting assembly of the subject invention are typically determined by the amount of thermal resistance or sound control desired and the depth of the cavities being insulated. Typically, the pre-cut fibrous insulation blankets are about three to about fourteen or more inches in thickness and approximate the depth of the cavities being insulated. For example, in a wall cavity defined in part by nominally 2×4 or 2×6 inch studs or framing members, a pre-cut resilient fibrous insulation blanket will have a thickness of about 3½ inches or about 5½ inches, respectively.
The preferred pre-cut resilient fibrous insulation blanket 20 formed by the compression-cutting assembly and/or method of the subject invention includes a plurality of longitudinally extending blanket sections, e.g. 5 blanket sections 22, formed in the resilient fibrous insulation blanket 20 by a plurality of longitudinally extending series 24 of alternating cuts 26 and separable connectors 28 located intermediate the blanket sections 22 of the resilient fibrous insulation blanket 20. Each longitudinally extending series 24 of alternating cuts and separable connectors is spaced laterally from each other longitudinally extending series 24 of cuts and separable connectors and laterally inward from the lateral edges of the resilient fibrous insulation blanket. The separable connectors 28 of each series 24 of the cuts and separable connectors separably join the adjacent blanket sections 22 of the pre-cut resilient fibrous insulation blanket along the length of the resilient fibrous insulation blanket 20 to hold the resilient fibrous insulation blanket together for handling and installation while being easily separable by hand to permit selective separation of adjacent blanket sections 22 to form a reduced width resilient fibrous insulation blanket of a desired or selected width.
As shown in
The spaced apart circular compression-cutting blades 38 are spaced apart across the widths of the fibrous insulation blankets 32 at locations selected to form blanket sections 22 of desired widths in each of the fibrous insulation blankets 32 being formed into a pre-cut fibrous insulation blanket 20. Preferably, the circular compression-cutting blades 38 are each rotatably mounted on a separate pneumatic piston assembly 40 that permits the compression-cutting blades 38 to be pressed against the moving anvil surface of the anvil with a selected pressure to effect the compression-cutting of the blanket 32 and drive the compression-cutting blades 38. As schematically shown in
Preferably, anvils that cooperate with the compression-cutting teeth of the compression-cutting blades 38 to crush and cut the fibers of the fibrous insulation blankets 32 and to drive the compression-cutting blades are either driven rotating cylindrical anvils such as the anvil 42 of
Each of the moving continuous belt anvils 44 may have a backing plate 50 opposite the compression-cutting blades 38 to provide a firm anvil surface opposite the compression cutting teeth of the compression-cutting blades 38 and enhance the crushing and cutting of the blanket fibers by the teeth of the compression cutting blades 38. The anvils 42 and 44 may have an elastomeric anvil surface, preferably urethane, which exhibits a durometer hardness between 60 A and 80 D.
The compression-cutting assemblies 30 work more effectively when the resilient fibrous insulation blankets 32 are compressed in thickness to make the resilient fibrous insulation blankets denser. Accordingly, one embodiment of the compression-cutting assemblies 30, shown in
As shown, the blanket compression plate 52 of each compression-cutting assembly 30 includes a leading or upstream portion 54 and an integral trailing or downstream portion 56. Preferably, the leading or upstream portion 54 of the blanket compression plate 52 is planar or substantially planar and extends entirely across the width of the resilient fibrous insulation blanket 32 being compression-cut by the compression-cutting assembly. The leading or upstream portion 56 of the blanket compression plate 52 also extends upstream and upward from the trailing or downstream portion 56 of the blanket compression plate 52, at an acute angle to the upper major surfaces of the incoming resilient fibrous insulation blankets 32, to a height greater than any normal thickness for the resilient fibrous insulation blankets being compression cut. Typically, the acute angle of the upstream portion 54 of the blanket compression plate 52 to the major surfaces of the incoming resilient fibrous insulation blankets 32 is between 30° and 60°.
Preferably, the trailing portion 56 of the blanket compression plate 52 is planar or substantially planar and extends across the width the resilient fibrous insulation blanket 32 being compression-cut by the compression-cutting assembly 30 in a plane parallel to or substantially parallel to the upper and lower major surfaces of the resilient fibrous insulation blankets. The trailing portion 56 contains a slit or elongated opening for each of the compression-cutting blades 38 and the lower portions of the compression-cutting blades 38 extend through the slits or elongated openings to crush and cut, in cooperation with the moving anvil surface, the fibers of the resilient fibrous insulation blankets 32 being formed into the pre-cut resilient fibrous insulation blankets 20. Preferably, the height of the trailing portion 56 of the blanket compression plate 52 above the moving anvil surface is adjustable to enable resilient fibrous insulation blankets 32 of various thicknesses and densities to be selectively compressed to a most effective thickness for the compression-cutting of the resilient fibrous insulation blankets 32 by the compression-cutting assembly 30. Other than the inclusion of the blanket compression plate 52, the compression-cutting assembly 30 of
Referring now to the compression-cutting blade 38 of
a) selecting a notch length NL for each of the notches in inches;
b) selecting a tooth length TL for each of the teeth in inches;
c) adding the notch length NL and tooth length TL to obtain a pitch length PL in inches;
d) inserting the notch length NL and the pitch length PL in the following empirical equation for finding a tear index TI:
TI=74.65−1330.4×NL−298.38×PL+15738×NL2+112.43×PL2−250.80×NL3−12.903×PL3;
e) solving for TI; and
f) where the TI is between −70 and +70, using the selected notch length and tooth length for the circular compression-cutting blade.
The tear index graph of
The following analysis shows the regression statistics for the tear index equation:
TI=74.65−1330.4×NL−298.38×PL+15738×NL2+112.43×PL2−25080×NL3−12.903×PL3.
In describing the invention, certain embodiments have been used to illustrate the invention and the practices thereof. However, the invention is not limited to these specific embodiments as other embodiments and modifications within the spirit of the invention will readily occur to those skilled in the art on reading this specification. Thus, the invention is not intended to be limited to the specific embodiments disclosed, but is to be limited only by the claims appended hereto.
This application is a division of application Ser. No. 10/114,618, filed Apr. 1, 2002 now U.S. Pat. No. 6,854,369.
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Number | Date | Country | |
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Parent | 10114618 | Apr 2002 | US |
Child | 11032361 | US |