Fibrous material can be formed into various products including webs, packs, batts and blankets. Packs of fibrous material can be used in many applications, including the non-limiting examples of insulation and sound-proofing for buildings and building components, appliances and aircraft. Packs of fibrous material are typically formed by processes that include fiberizers, forming hoods, ovens, trimming and packaging machines. Typical processes also include the use of wet binders, binder reclaim water and washwater systems.
The present application discloses an insulation pad and a variety of different insulation materials that can be used in the insulation pad. In one exemplary embodiment, the insulation pad includes a binderless pack of glass fibers and an envelope around the binderless pack of glass fibers. The glass fibers are mechanically entangled by needling such that the binderless pack has a density of from 4.5 to 5.5 pounds per cubic foot. The insulation pad is used to insulate pipes and vessels.
Other advantages of the webs, batts, and methods of producing the webs and batts will become apparent to those skilled in the art from the following detailed description, when read in view of the accompanying drawings.
The present invention will now be described with occasional reference to the specific exemplary embodiments of the invention. This invention may, however, be embodied in different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art.
Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for describing particular embodiments only and is not intended to be limiting of the invention. As used in the description of the invention and the appended claims, the singular forms “a,” “an,” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise.
Unless otherwise indicated, all numbers expressing quantities of dimensions such as length, width, height, and so forth as used in the specification and claims are to be understood as being modified in all instances by the term “about.” Accordingly, unless otherwise indicated, the numerical properties set forth in the specification and claims are approximations that may vary depending on the desired properties sought to be obtained in embodiments of the present invention. Notwithstanding that the numerical ranges and parameters setting forth the broad scope of the invention are approximations, the numerical values set forth in the specific examples are reported as precisely as possible. Any numerical values, however, inherently contain certain errors necessarily resulting from error found in their respective measurements.
The description and figures disclose an improved method of forming a pack from fibrous materials. Generally, the improved continuous methods replace the traditional methods of applying a wet binder to fiberized materials with new methods of making a batt or pack of fibers without any binder (i.e. material that binds fibers together) and/or new methods of making a batt or pack of fibers with dry binders.
The term “fibrous materials”, as used herein, is defined to mean any material formed from drawing or attenuating molten materials. The term “pack”, as used herein, is defined to mean any product formed by fibrous materials that are joined together by an adhesive and/or by mechanical entanglement.
Referring to
Referring back to
The long and thin fibers may take a wide variety of different forms. In an exemplary embodiment, the long and thin fibers have a length in a range of from about 0.25 inches to about 10.0 inches and a diameter dimension in a range of from about 9 HT to about 35 HT. HT stands for hundred thousandths of an inch. In an exemplary embodiment, the fibers 322 have a length in a range of from about 1.0 inch to about 5.0 inches and a diameter dimension in a range of from about 14 HT to about 25 HT. In an exemplary embodiment, the fibers 322 have a length of about 3 inches and an average diameter of about 16-17 HT. While not being bound by the theory, it is believed the use of the relatively long and thin fibers advantageously provides a pack having better thermal and acoustic insulative performance, as well as better strength properties, such as higher tensile strength and/or higher bond strength, than a similar sized pack having shorter and thicker fibers.
In exemplary embodiments where the fibers are glass fibers, the term binderless means that the fibrous material, web, and/or pack comprises 99% or 100% glass only or 99% or 100% glass plus inert content. Inert content is any material that does not bind the glass fibers together. For example, in exemplary binderless embodiments described herein, the glass fibers 322 can optionally be coated or partially coated with a lubricant after the glass fibers are formed. For example, the glass fibers 322 can be coated with any lubricating material that does not bind the glass fibers together. In an exemplary embodiment, the lubricant can be a silicone compound, such as siloxane, dimethyl siloxane and/or silane. The lubricant can also be other materials or combinations of materials, such as, oil or an oil emulsion. The oil or oil emulsion may be a mineral oil or mineral oil emulsion and/or a vegetable oil or vegetable oil emulsion.
The glass fibers can be coated or partially coated with a lubricant in a wide variety of different ways. For example, the lubricant can be sprayed onto the glass fibers 322. In an exemplary embodiment, the lubricant is configured to prevent damage to the glass fibers 322 as the glass fibers 322 move through the manufacturing process and come into contact with various apparatus as well as other glass fibers. The lubricant can also be useful to reduce dust in the manufacturing process. The application of the optional lubricant can be precisely controlled by any desired structure, mechanism or device.
Referring to
The forming apparatus 332 can be configured to form a continuous dry web 321 of fibrous material having a desired thickness. In one exemplary embodiment, the dry webs 321 disclosed in this application can have a thickness in the range of about 0.25 inches to about 4 inches thick and a density in the range of about 0.2 lb/ft3 to about 0.6 lb/ft3. In one exemplary embodiment, the dry webs 321 disclosed in this application can have a thickness in the range of about 1 inch to about 3 inches thick and a density in the range of about 0.3 lb/ft3 to about 0.5 lb/ft3. In one exemplary embodiment, the dry webs 321 disclosed in this application can have a thickness of about 1.5 inches and a density of about 0.4 lb/ft3. The forming apparatus 332 can take a wide variety of different forms. Any arrangement for forming a dry web 321 of glass fibers can be used.
In one exemplary embodiment, the forming apparatus 332 includes a rotating drum with forming surfaces and areas of higher or lower pressure. Referring to
A low area weight web 321 having an area weight of about 5 to about 50 grams per square foot. The low area weight web may have the density and thickness ranges mentioned above. The low area weight web may have a thickness in the range of about 0.25 inches to about 4 inches thick, about 1 inch to about 3 inches thick, or about 1.5 inches. The low area weight web may have a density in the range of about 0.2 lb/ft3 to about 0.6 lb/ft3, about 0.3 lb/ft3 to about 0.5 lb/ft3 or about 0.4 lb/ft3. Referring to
In one exemplary embodiment, the fibers 322 of the web 321 are manipulated to align the fibers with one directions of the web than in the other directions of the web. This alignment can be achieved in a wide variety of different ways. For example, the fibers 322 can be stretched before or as they are formed into the web 321 by the forming apparatus 332. The fibers 322 can also be aligned by stretching the web 321 after the web 321 is formed by the forming apparatus. The fibers 322 can also be aligned by applying the fibers to the rotating drum 462 (See
In one exemplary embodiment, the fibers 322 of the web 321 are manipulated to align the fibers more with a direction of travel 390 (See
In one exemplary embodiment, the fibers 322 of the web 321 are manipulated to align the fibers more with a direction of the width of the web than in the direction of travel 390 and more than in the direction of the thickness of the web. This alignment can be achieved in a wide variety of different ways. For example, the fibers 322 can be stretched before or as they are formed into the web 321 by the forming apparatus 332. The fibers 322 can also be aligned by stretching the web 321 in the direction of the width of the web after the web 321 is formed by the forming apparatus. The fibers can also be aligned with a width of a layered web 350 by stretching the web 321 in the direction of travel 390 before the web is lapped to define the width of the layered web, for example by a cross-lapping mechanism that cross-laps the web 321 at 90 degrees to the machine direction 390. The fibers can also be aligned by stretching the layered web 350 in the direction of the width of the layered web after the web 321 is layered, for example by a cross-lapping mechanism. The fibers 322 can also be aligned in the direction of the width of the web 321 or the width of the layered web by applying the fibers to the rotating drum 462 (See
In one exemplary embodiment, the fibers 322 of the web 321 are manipulated to align the fibers more with a direction of the thickness of the web than in the direction of travel 390 and more than in the direction of the width of the web. This alignment can be achieved in a wide variety of different ways. For example, the fibers 322 can be aligned by bunching, compressing, or accordianing the web 321 in the direction of travel 390 of the web after the web 321 is formed by the forming apparatus. The fibers can also be aligned with a thickness of a layered web 350 bunching, compressing, or accordianing the web 321 in the direction of travel 390 before the web is lapped, for example by a cross-lapping mechanism. The fibers can also be aligned by bunching, compressing, or accordianing the layered web 350 in the direction of the width of the layered web and/or in the direction of travel 390 after the web 321 is layered. Webs and layered webs with aligned fibers in the direction of the width of the web can be used in any of the embodiments of the present invention. In one exemplary embodiment, the alignment of the fibers increases the compressive strength, increases the thickness, and/or increases the area weight of the web 321, layered webs 350 made from the web 321, and any products made from the webs 321 or layered webs 350. The web 321 with aligned fibers may be entangled as described herein or not entangled. A binder may be applied to the aligned fibers as described herein or the web 321.
In the example illustrated by
In one exemplary embodiment, the layering mechanism 332 is a lapping mechanism or a cross-lapping mechanism that functions in association with a conveyor 336. The conveyor 336 is configured to move in a machine direction as indicated by the arrow D1. The lapping or cross-lapping mechanism is configured to receive the continuous web 321 and deposit alternating layers of the continuous web on the first conveyer 336 as the first conveyor moves in machine direction D1. In the deposition process, a lapping mechanism 334 would form the alternating layers in a machine direction as indicated by the arrows D1 or the cross-lapping mechanism 334 would form the alternating layers in a cross-machine direction. Additional webs 321 may be formed and lapped or cross-lapped by additional lapping or cross-lapping mechanisms to increase the number of layers and throughput capacity.
In one exemplary embodiment, a cross-lapping mechanism is configured to precisely control the movement of the continuous web 321 and deposit the continuous web on the conveyor 336 such that the continuous web is not damaged. The cross-lapping mechanism can include any desired structure and can be configured to operate in any desired manner. In one exemplary embodiment, the cross-lapping mechanism includes a head (not shown) configured to move back and forth at 90 degrees to the machine direction D1. In this embodiment, the speed of the moving head is coordinated such that the movement of the head in both cross-machine directions is substantially the same, thereby providing uniformity of the resulting layers of the fibrous body. In an exemplary embodiment, the cross-lapping mechanism comprises vertical conveyors (not shown) configured to be centered with a centerline of the conveyor 336. The vertical conveyors are further configured to swing from a pivot mechanism above the conveyor 336 such as to deposit the continuous web on the conveyor 336. While multiple examples of cross lapping mechanisms have been described above, it should be appreciated that the cross-lapping mechanism can be other structures, mechanisms or devices or combinations thereof.
The layered web 350 can have any desired thickness. The thickness of the layered web is a function of several variables. First, the thickness of the layered web 350 is a function of the thickness of the continuous web 321 formed by the forming apparatus 332. Second, the thickness of the layered web 350 is a function of the speed at which the layering mechanism 334 deposits layers of the continuous web 321 on the conveyer 336. Third, the thickness of the layered web 334 is a function of the speed of the conveyor 336. In the illustrated embodiment, the layered web 350 has a thickness in a range of from about 0.1 inches to about 20.0 inches. In an exemplary embodiment, a cross lapping mechanism 334 may form a layered web 350 having from 1 layer to 60 layers. Optionally, a cross-lapping mechanisms can be adjustable, thereby allowing the cross-lapping mechanisms 334 to form a pack having any desired width. In certain embodiments, the pack can have a general width in a range of from about 98.0 inches to about 236.0 inches.
In one exemplary embodiment, the layered web 350 is produced in a continuous process indicated by dashed box 101 in
In one exemplary embodiment, the web 321 is relatively thick and has a low area weight, yet the continuous process has a high throughput and all of the fibers produced by the fiberizer are used to make the web. For example, a single layer of the web 321 may have an area weight of about 5 to about 50 grams per square foot. The low area weight web may have the density and thickness ranges mentioned above. The high output continuous process may produce between about 750 lbs/hr and 1500 lbs/hr, such as at least 900 lbs/hr or at least 1250 lbs/hr. The layered web 350 can be used in a wide variety of different applications.
Referring to
Referring to
In the one exemplary embodiment, the entanglement device 345 comprises more than 1 entangling unit or loom. The multiple entangling units or looms can be the same or can have different configurations. Any number of entangling units or looms can be included. In one exemplary embodiment, the entanglement device 345 may be configured to entangle the web 321 and/or the layered web 350 from the top and/or from the bottom any number of times and in any order. For example, the entanglement device 345 may comprise any combination of any two or more of the entanglement devices illustrated by
In some exemplary embodiments, the entanglement device provides more entanglement of the fibers on one side of the web 321 than the other side of the web, provides different types of entanglement at different areas of the web, such as at different depths of the web 321 and/or different sides of the web. In one exemplary embodiment, the fibers 322 of the web 321 are optionally manipulated by the entanglement device to align the fibers or portions of the fibers of the web 321 more with a direction of travel 390 of the web than in the direction of the width of the web and more than in the direction of the thickness of the web.
In the exemplary embodiment illustrated by
In the exemplary embodiment illustrated by
In one exemplary embodiment, the entangling devices are configured to advance in synchronism or in substantial synchronism with the advancement of the web 321 in the direction indicated by arrow 1750. For example, the entangling units may advance in the direction of arrow 390 while engagement with the web 321 and then return to an original or home position when spaced apart from the web. The rotational speed of the rotary tackers 1702 and/or eliptical looms 2402 can be selected based on the speed of the web 321 to provide the synchronism or substantial synchronism of the entangling device with the speed of the web 321.
As with all of the embodiments of the present application, the web 321 can be layered before the mechanical entanglement of the
The entangled web 352 of the can have any desired thickness. The thickness of the entangled web is a function of the thickness of the continuous web 321 formed by the forming apparatus 332 and the amount of compression of the continuous web 321 by the entanglement mechanism 345. In an exemplary embodiment, the entangled web 352 has a thickness in a range of from about 0.1 inches to about 2.0 inches. In an exemplary embodiment, the entangled web 352 has a thickness in a range of from about 0.5 inches to about 1.75 inches. For example, in one exemplary embodiment, the thickness of the entangled web is about ½″.
In one exemplary embodiment, the entangled web 352 is produced in a continuous process 151. The fibers produced by the fiberizer 318 are sent directly to the forming apparatus 332 (i.e. the fibers are not collected and packed and then unpacked for use at a remote forming apparatus). The web 321 is provided directly to the entangling device 345 (i.e. the web is not formed and rolled up and then unrolled for use at a remote entangling device 345). The entangled web 352 can be used in a wide variety of different applications. In an exemplary embodiment of the continuous process, each of the processes (forming and entangling in
The high density entangled web 352 of
Referring to
The entangled pack 370 of layered webs 350 can have any desired thickness. The thickness of the entangled pack is a function of several variables. First, the thickness of the entangled pack is a function of the thickness of the continuous web 321 formed by the forming apparatus 332. Second, the thickness of the entangled pack 370 is a function of the speed at which the lapping or cross-lapping mechanism 334 deposits layers of the continuous web 321 on the conveyer 336. Third, the thickness of the entangled pack 370 is a function of the speed of the conveyor 336. Fourth, the thickness of the entangled pack 370 is a function of the amount of compression of the layered webs 350 by the entanglement mechanism 345. The entangled pack 370 can have a thickness in a range of from about 0.1 inches to about 20.0 inches. In an exemplary embodiment, the entangled pack 370 may having from 1 layer to 60 layers. Each entangled web layer 352 may be from 0.1 to 2 inches thick. For example, each entangled web layer may be about 0.5 inches thick.
In one exemplary embodiment, the entangled pack 370 is produced in a continuous process. The fibers produced by the fiberizer 318 are sent directly to the forming apparatus 332 (i.e. the fibers are not collected and packed and then unpacked for use at a remote forming apparatus). The web 321 is provided directly to the layering device 352 (i.e. the web is not formed and rolled up and then unrolled for use at a remote layering device 352). The layered web 350 is provided directly to the entangling device 345 (i.e. the layered web is not formed and rolled up and then unrolled for use at a remote entangling device 345). In an exemplary embodiment of the continuous process, each of the processes (forming, layering, and entangling in
In one exemplary embodiment, the entangled pack 370 of layered webs is made from a web 321 or webs that is relatively thick and has a low area weight, yet the continuous process has a high throughput and all of the fibers produced by the fiberizer are used to make the entangled pack. For example, a single layer of the web 321 may have the arca weights, thicknesses, and densities mentioned above. The high output continuous process may produce between about 750 lbs/hr and 1500 lbs/hr, such as at least 900 lbs/hr or at least 1250 lbs/hr. In an exemplary embodiment, the combination of high web throughput and mechanical entanglement, such as needling, of a continuous process is facilitated by layering of the web 321, such as lapping or cross-lapping of the web. By layering the web 321, the linear speed of the material moving through the layering device is slower than the speed at which the web is formed. For example, in a continuous process, a two layer web will travel through the entangling apparatus 345 at ½ the speed at which the web is formed (3 layers-⅓ the speed, etc.). This reduction in speed allows for a continuous process where a high throughput, low area weight web 321 is formed and converted into a multiple layer, mechanically entangled pack 370. The entangled pack 370 of layered webs can be used in a wide variety of different applications.
In an exemplary embodiment, the layering and entangling of the long, thin fibers results in a strong web 370. For example, the entanglement of the long, thin glass fibers described in this application results in a layered, entangled web with a high tensile strength and a high bond strength. Tensile strength is the strength of the web 370 when the web is pulled in the direction of the length or width of the web. Bond strength is the strength of the web when the web 370 is pulled apart in the direction of the thickness of the web.
Tensile strength and bond strength may be tested in a wide variety of different ways. In one exemplary embodiment, a machine, such as an Instron machine, pulls the web 370 apart at a fixed speed (12 inches per second in the examples described below) and measures the amount of force required to pull the web apart. Forces required to pull the web apart, including the peak force applied to the web before the web rips or fails, are recorded.
In one method of testing tensile strength, the tensile strength in the length direction is measured by clamping the ends of the web along the width of the web, pulling the web 370 along the length of the web with the machine at the fixed speed (12 inches per second in the examples provided below), and recording the peak force applied in the direction of the length of the web. The tensile strength in the width direction is measured by clamping the sides of the web along the width of the web, pulling the web 370 along the width of the web at the fixed speed (12 inches per second in the examples provided below), and recording the peak force applied. The tensile strength in the length direction and the tensile strength in the width direction are averaged to determine the tensile strength of the sample.
In one method of testing bond strength, a sample of a predetermined size (6″ by 6″ in the examples described below) is provided. Each side of the sample is bonded to a substrate, for example by gluing. The substrates on the opposite side of the sample are pulled apart with the machine at the fixed speed (12 inches per second in the examples provided below), and recording the peak force applied. The peak force applied is divided by the area of the sample (6″ by 6″ in the examples described below) to provide the bond strength in terms of force over area.
The following examples are provided to illustrate the increased strength of the layered, entangled web 370. In these examples, no binder is included. That is, no aqueous or dry binder is included. These examples do not limit the scope of the present invention, unless expressly recited in the claims. Examples of layered, entangled webs having 4, 6, and 8 layers are provided. However, the layered entangled web 370 may be provided with any number of layers. The layered, entangled web 370 sample length, width, thickness, number of laps, and weight may vary depending on the application for the web 370. In the dense, single layer embodiment illustrated by
In one exemplary embodiment, a web 370 sample that is 6 inches by 12 inches, has multiple layers, such as two laps (i.e. four layers), is between 0.5 inches thick and 2.0 inches thick, has a weight per square foot between 0.1 and 0.3 lbs/sq ft, has a tensile strength that is greater than 3 lbf, and has a tensile strength to weight ratio that is greater than 40 lbf/lbm, such as from about 40 to about 120 lbf/lbm. In an exemplary embodiment, a bond strength of this sample is greater than 0.1 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 5 lbf. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 7.5 lbf. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 10 lbf. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 12.5 lbf. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 13.75 lbf. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is between 3 and 15 lbf. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 2 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 5 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 10 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 15 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 20 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 5 lbf and the bond strength is greater than 2 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 7.5 lbf and the bond strength is greater than 7.5 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 10 lbf and the bond strength is greater than 10 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 12.5 lbf and the bond strength is greater than 15 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 13.75 lbf and the bond strength is greater than 20 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is between 3 and 15 lbf and the bond strength is between 0.3 and 30 lbs/sq ft.
In one exemplary embodiment, a web 370 sample that is 6 inches by 12 inches, has multiple layers, such as two laps (i.e. four layers), is between 0.5 inches thick and 1.75 inches thick, has a weight per square foot between 0.12 and 0.27 lbs/sq ft, has a tensile strength that is greater than 3 lbf, and has a tensile strength to weight ratio that is greater than 40 lbf/lbm, such as from about 40 to about 120 lbf/lbm, and a bond strength that is greater than 1 lb/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 5 lbf. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 7.5 lbf. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 10 lbf. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 12.5 lbf. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 13.75 lbf. In one exemplary embodiment, the tensile strength of the sample described in this paragraph is between 3 and 15 lbf. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 2 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 5 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 10 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 15 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 20 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 5 lbf and the bond strength is greater than 2 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 7.5 lbf and the bond strength is greater than 7.5 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 10 lbf and the bond strength is greater than 10 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 12.5 lbf and the bond strength is greater than 15 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 13.75 lbf and the bond strength is greater than 20 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is between 3 and 15 lbf and the bond strength is between 0.3 and 30 lbs/sq ft.
In one exemplary embodiment, a web 370 sample that is 6 inches by 12 inches, has multiple layers, such as two laps (i.e. four layers), is between 0.5 inches thick and 1.25 inches thick, has a weight per square foot between 0.2 and 0.3 lbs/sq ft, has a tensile strength that is greater than 10 lbf, and has a tensile strength to weight ratio that is greater than 75 lbf/lbm, such as from about 75 about 120 lbf/lbm. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 12.5 lbf. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 13.75 lbf. In one exemplary embodiment, the tensile strength of the sample described in this paragraph is between 3 and 15 lbf. In one exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 3 lb/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 10 lb/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 15 lb/sq ft. In one exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 10 lbf and the bond strength is greater than 3 lb/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 12.5 lbf and the bond strength is greater than 10 lb/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 13.75 lbf and the bond strength is greater than 15 lb/sq ft.
In one exemplary embodiment, a web 370 sample that is 6 inches by 12 inches, has multiple layers, such as three laps (i.e. six layers), is between 1.0 inches thick and 2.25 inches thick, has a weight per square foot between 0.15 and 0.4 lbs/sq ft, has a tensile strength that is greater than 5 lbf, and has a tensile strength to weight ratio that is greater than 40 lbf/lbm, such as from about 40 to about 140 lbf/lbm. In an exemplary embodiment, the bond strength of this sample is greater than 0.1 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 7.5 lbf. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 10 lbf. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 12.5 lbf. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 13.75 lbf. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is between 5 and 20 lbf. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 0.5 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 1.0 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 1.5 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 2.0 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 2.5 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 3.0 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 7.5 lbf and the bond strength is greater than 0.40 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 10 lbf and the bond strength is greater than 0.6 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 12.5 lbf and the bond strength is greater than 0.9 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is between 5 and 20 lbf and the bond strength is between 0.1 and 4 lbs/sq ft.
In one exemplary embodiment, a web 370 sample that is 6 inches by 12 inches, has multiple layers, such as three laps (i.e. six layers), is between 1.0 inches thick and 1.50 inches thick, and has a weight per square foot between 0.25 and 0.4 lbs/sq ft, has a tensile strength that is greater than 9 lbf, and has a tensile strength to weight ratio that is greater than 50 lbf/lbm, such as from about 50 to about 140 lbf/lbm. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 12.5 lbf. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 13.75 lbf. In one exemplary embodiment, the tensile strength of the sample described in this paragraph is between 9 and 15 lbf. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 0.5 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 1.0 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 1.5 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 2.0 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 2.5 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 3.0 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 9 lbf and a bond strength that is greater than 0.5 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 12.5 lbf and a bond strength that is greater than 1.0 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 13.75 lbf and a bond strength that is greater than 2 lbs/sq ft.
In one exemplary embodiment, a web 370 sample that is 6 inches by 12 inches, has multiple layers, such as four laps (i.e. eight layers), is between 0.875 inches thick and 2.0 inches thick, and has a weight per square foot between 0.15 and 0.4 lbs/sq ft, has a tensile strength that is greater than 3 lbf, and has a tensile strength to weight ratio that is greater than 40 lbf/lbm, such as from about 40 to about 130 lbf/lbm. In one exemplary embodiment, the web has a bond strength that is greater than 0.3 lbs/sq ft. In an exemplary embodiment, the bond strength of this sample is greater than 0.1 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 7.5 lbf. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 10 lbf. In one exemplary embodiment, the tensile strength of the sample described in this paragraph is between 3 and 15 lbf. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 0.5 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 1.0 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 2 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 3 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 4 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 5 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 10 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 7.5 lbf and the bond strength is greater than 0.5 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 10 lbf and the bond strength is greater than 1.0 lbs/sq ft. In one exemplary embodiment, the tensile strength of the sample described in this paragraph is between 3 and 15 lbf and the bond strength is between 0.3 and 15 lbs/sq ft.
In one exemplary embodiment, a web 370 sample that is 6 inches by 12 inches, has multiple layers, such as four laps (i.e. eight layers), is between 1.0 inches thick and 2.0 inches thick, and has a weight per square foot between 0.1 and 0.3 lbs/sq ft, has a tensile strength that is greater than 9 lbf, and has a tensile strength to weight ratio that is greater than 70 lbf/lbm. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 10 lbf. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 0.5 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 1.0 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 2 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 3 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 4 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 5 lbs/sq ft. In an exemplary embodiment, the bond strength of the sample described in this paragraph is greater than 10 lbs/sq ft. In an exemplary embodiment, the tensile strength of the sample described in this paragraph is greater than 10 lbf and the bond strength is greater than 5 lbs/sq ft.
In one exemplary embodiment, an entangled web made in accordance
US Published Application Pub. No. 2010/0151223; and/or U.S. Pat. Nos. 6,527,014; 5,932,499; 5,523,264; and 5,055,428 are incorporated by reference in their entirety. In one exemplary embodiment, the fiber diameters and fiber lengths identified in this application refer to a majority of the fibers of a group of fibers that are provided by a fiberizer or other fiber forming apparatus, but are not otherwise processed after formation of the fibers. In another exemplary embodiment, the fiber diameters and fiber lengths identified in this application refer a group of fibers that are provided by a fiberizer or other fiber forming apparatus, but are not otherwise processed after formation of the fibers, where a minority or any number of the fibers have the fiber diameter and/or fiber length.
Referring to
In one exemplary embodiment, the dry binder is applied to the fibers 322 at a location that is significant distance downstream from the fiberizer 318. For example, the dry binder may be applied to the fibers at a location where the temperature of the fibers and/or a temperature of the air surrounding the fibers is significantly lower than the temperature of the fibers and the surrounding air at the fiberizer. In one exemplary embodiment, the dry binder is applied at a location where a temperature of the fibers and/or a temperature of air that surrounds the fibers is below a temperature at which the dry binder melts or a temperature at which the dry binder fully cures or reacts. For example, a thermoplastic binder may be applied at a point in the production line where a temperature of the fibers 322 and/or a temperature of air that surrounds the fibers are below the melting point of the thermoplastic binder. A thermoset binder may be applied at a point in the production line where a temperature of the fibers 322 and/or a temperature of air that surrounds the fibers are below a curing temperature of the thermoset binder. That is, the thermoset binder may be applied at a point where a temperature of the fibers 322 and/or a temperature of air that surrounds the fibers is below a point where the thermoset binder fully reacts or full cross-linking of the thermoset binder occurs. In one exemplary embodiment, the dry binder is applied at a location in the production line where the temperature of the fibers 322 and/or a temperature of air that surrounds the fibers are below 300 degrees F. In one exemplary embodiment, the dry binder is applied at a location in the production line where the temperature of the fibers 322 and/or a temperature of air that surrounds the fibers are below 250 degrees F. In one exemplary embodiment, the temperature of the fibers and/or a temperature of air that surrounds the fibers at the locations indicated by arrows 527, 529, 531, 533, and 535 in
In one exemplary embodiment, the binder applicator is a sprayer configured for dry powders. The sprayer may be configured such that the force of the spray is adjustable, thereby allowing more or less penetration of the dry powder into the continuous web of fibrous material. Alternatively, the binder applicator can be other structures, mechanisms or devices or combinations thereof, such as for example a vacuum device, sufficient to draw the dry binder into the continuous web 321 of glass fibers. For example, the dry binder may comprise binder fibers that are provided in bale form. The binder applicator comprises a bale opener and blower that opens the bale, separates the binder fibers from one another, and blows the binder fibers into the duct where the binder is mixed with the fiberglass fibers. The dry binder may comprise a powder. The binder applicator may comprise a screw delivery device that delivers the binder powder to an air nozzle that delivers the binder powder into the duct, where the binder powder is mixed with the fibers. The dry binder may comprise a non-aqueous liquid. The binder applicator may comprise a nozzle that delivers the liquid binder into the duct, where the binder is mixed with the fibers.
Referring to
Referring to
The air lapper 902 illustrated by
Referring to
The dry binder can take a wide variety of different forms. Any non-aqueous medium that holds the fibers 322 together to form a web 521 can be used. In one exemplary embodiment, the dry binder, while being initially applied to the fibers, is comprised of substantially 100% solids. The term “substantially 100% solids”, as used herein, means any binder material having diluents, such as water, in an amount less than or equal to approximately two percent, and preferably less than or equal to one percent by weight of the binder (while the binder is being applied, rather than after the binder has dried or cured). However, it should be appreciated that certain embodiments, the binder can include diluents, such as water, in any amount as desired depending on the specific application and design requirements. In one exemplary embodiment, the dry binder is a thermoplastic resin-based material that is not applied in liquid form and further is not water based. In other embodiments, the dry binder can be other materials or other combinations of materials, including the non-limiting example of polymeric thermoset resins. The dry binder can have any form or combinations of forms including the non-limiting examples of powders, particles, fibers and/or hot melt. Examples of hot melt polymers include, but are not limited to, ethylene-vinyl acetate copolymer, ethylene-acrylate copolymer, low density polyethylene, high density polyethylene, atactic polypropylene, polybutene-1, styrene block copolymer, polyamide, thermoplastic polyurethane, styrene block copolymer, polyester and the like. In one exemplary embodiment, the dry binder is a no added formaldehyde dry binder, which means that the dry binder contains no formaldehyde. However, formaldehyde may be formed if the formaldehyde free dry binder is burned. In one exemplary embodiment, sufficient dry binder is applied such that a cured fibrous pack can be compressed for packaging, storage and shipping, yet regains its thickness—a process known as “loft recovery”—when installed.
In the examples illustrated by
Referring to
In an exemplary embodiment, the dry binder of the continuous web 521 is configured to be thermally set in a curing oven 550. In an exemplary embodiment, the curing oven 550 replaces the entanglement mechanism 345, since the dry binder holds the fibers 322 together. In another exemplary embodiment, both a curing oven 550 and an entanglement mechanism 345 are included.
Referring to
The flow of hot gases can be created by optional blowing mechanisms, such as the non-limiting examples of annular blowers (not shown) or annular burners (not shown). Generally, the blowing mechanisms are configured to direct the veil 620 of glass fibers 622 in a given direction, usually in a downward manner. It should be understood that the flow of hot gasses can be created by any desired structure, mechanism or device or any combination thereof.
As shown in
Optionally, the glass fibers 622 can be coated with a lubricant after the glass fibers are formed. In the illustrated embodiment, a plurality of nozzles 628 can be positioned around the veils 620 at a position beneath the rotary fiberizers 618. The nozzles 628 can be configured to supply a lubricant (not shown) to the glass fibers 622 from a source of lubricant (not shown).
The application of the lubricant can be precisely controlled by any desired structure, mechanism or device, such as the non-limiting example of a valve (not shown). In certain embodiments, the lubricant can be a silicone compound, such as siloxane, dimethyl siloxane, and/or silane. The lubricant can also be other materials or combinations of materials, such as for example an oil or an oil emulsion. The oil or oil emulsion may be a mineral oil or mineral oil emulsion and/or a vegetable oil or vegetable oil emulsion. In an exemplary embodiment, the lubricant is applied in an amount of about 1.0 percent oil and/or silicone compound by weight of the resulting pack of fibrous materials. However, in other embodiments, the amount of the lubricant can be more or less than about 1.0 percent oil and/or silicone compound by weight.
While the embodiment shown in
In the illustrated embodiment, the glass fibers 622, entrained within the flow of hot gases, can be gathered by an optional gathering member 624. The gathering member 624 is shaped and sized to easily receive the glass fibers 622 and the flow of hot gases. The gathering member 624 is configured to divert the glass fibers 622 and the flow of hot gases to a duct 630 for transfer to downstream processing stations, such as for example forming apparatus 632a and 632b. In other embodiments, the glass fibers 622 can be gathered on a conveying mechanism (not shown) such as to form a blanket or batt (not shown). The batt can be transported by the conveying mechanism to further processing stations (not shown). The gathering member 624 and the duct 630 can be any structure having a generally hollow configuration that is suitable for receiving and conveying the glass fibers 622 and the flow of hot gases. While the embodiment shown in
In the embodiment shown in
Referring again to
Referring now to
In the embodiment illustrated in
Referring again to
In an exemplary embodiment, the dry binder is a thermoplastic resin-based material that is not applied in liquid form and further is not water based. In other embodiments, the dry binder can be other materials or other combinations of materials, including the non-limiting example of polymeric thermoset resins. The dry binder can have any form or combinations of forms including the non-limiting examples of powders, particles, fibers and/or hot melt. Examples of hot melt polymers include, but are not limited to, ethylene-vinyl acetate copolymer, ethylene-acrylate copolymer, low density polyethylene, high density polyethylene, atactic polypropylene, polybutene-1, styrene block copolymer, polyamide, thermoplastic polyurethane, styrene block copolymer, polyester and the like. Sufficient dry binder is applied such that a cured fibrous pack can be compressed for packaging, storage and shipping, yet regains its thickness—a process known as “loft recovery”—when installed. Applying the dry binder to the continuous web of fibrous material forms a continuous web, optionally with unreacted binder.
In the embodiment illustrated by
While the embodiment illustrated in
Referring again to
In the illustrated embodiment, the cross-lapping mechanisms 634a and 634b are devices configured to precisely control the movement of the continuous web with unreacted binder and deposit the continuous web with unreacted binder on the first conveyor 636 such that the continuous web, optionally with unreacted binder, is not damaged. The cross-lapping mechanisms 634a and 634b can include any desired structure and can be configured to operate in any desired manner. In one example, the cross-lapping mechanisms 634a and 634b can include a head (not shown) configured to move back and forth in the cross-machine direction D2. In this embodiment, the speed of the moving head is coordinated such that the movement of the head in both cross-machine directions is substantially the same, thereby providing uniformity of the resulting layers of the fibrous body. In another example, vertical conveyors (not shown) configured to be centered with a centerline of the first conveyor 636 can be utilized. The vertical conveyors are further configured to swing from a pivot mechanism above the first conveyor 636 such as to deposit the continuous web, optionally with unreacted binder, on the first conveyor 36. While several examples of cross lapping mechanisms have been described above, it should be appreciated that the cross-lapping mechanisms 634a and 634b can be other structures, mechanisms or devices or combinations thereof.
Referring again to
The layered web or pack can have any desired thickness. The thickness of the pack is a function of several variables. First, the thickness of the pack is a function of the thickness of the continuous web, optionally with unreacted binder, formed by each of the forming apparatus 632a and 632b. Second, the thickness of the pack is a function of the speed at which the cross-lapping mechanisms 634a and 634b alternately deposit layers of the continuous web, optionally with unreacted binder, on the first conveyer 636. Third, the thickness of the pack is a function of the speed of the first conveyor 636. In the illustrated embodiment, the pack has a thickness in a range of from about 0.1 inches to about 20.0 inches. In other embodiments, the pack can have a thickness less than about 0.1 inches or more than about 20.0 inches.
As discussed above, the cross lapping mechanisms 634a and 634b are configured to deposit alternating layers of the continuous web, optionally with unreacted binder, on the first conveyer 636 as the first conveyor 636 moves in machine direction D1, thereby forming layers of a fibrous body. In the illustrated embodiment, the cross lapping mechanism 634a and 634b and the first conveyor 636 are coordinated such as to form a fibrous body having a quantity of layers in a range of from about 1 layer to about 60 layers. In other embodiments, the cross lapping mechanism 634a and 634b and the first conveyor 636 can be coordinated such as to form a fibrous body having any desired quantity of layers, including a fibrous body having in excess of 60 layers.
Optionally, the cross-lapping mechanisms 634a and 634b can be adjustable, thereby allowing the cross-lapping mechanisms 634a and 634b to form a pack having any desired width. In certain embodiments, the pack can have a general width in a range of from about 98.0 inches to about 236.0 inches. Alternatively, the pack can have a general width less than about 98.0 inches or more than about 236.0 inches.
While the cross-lapping mechanisms 634a and 634b have been described above as being jointly involved in the formation of a fibrous body, it should be appreciated that in other embodiments, the cross-lapping mechanisms 634a and 634b can operate independently of each other such as to form discrete lanes of fibrous bodies.
Referring to
In the illustrated embodiment, the optional trim mechanism 640 includes a saw system having a plurality of rotating saws (not shown) positioned on either side of the pack. Alternatively, the trim mechanism 640 can be other structures, mechanisms or devices or combinations thereof including the non-limiting examples of water jets, compression knives.
In the illustrated embodiment, the trim mechanism 640 is advantageously positioned upstream from the curing oven 650. Positioning the trim mechanism 640 upstream from the curing oven 650 allows the pack to be trimmed before the pack is thermally set in the curing oven 650. Optionally, materials that are trimmed from the pack by the trim mechanism 640 can be returned to the flow of gasses and glass fibers in the ducts 630 and recycled in the forming apparatus 632a and 632b. Recycling of the trim materials advantageously prevents potential environmental issues connected with the disposal of the trim materials. As shown in
The trimmed pack is conveyed by the first conveyor 636 to a second conveyor 644. As shown in
Referring again to
The second conveyor 644 conveys the pack with optional dry binder, that is optionally trimmed, and/or optionally entangled (hereafter both the trimmed pack and the entangled pack are simply referred to as the “pack”) to a third conveyor 648. When the pack includes a dry binder, the third conveyor 648 is configured to carry the pack to an optional curing oven 650. The curing oven 650 is configured to blow a fluid, such as for example, heated air through the pack such as to cure the dry binder and rigidly bond the glass fibers 622 together in a generally random, three-dimensional structure. Curing the pack in the curing oven 650 forms a cured pack.
As discussed above, the pack optionally includes a dry binder. The use of the dry binder, rather than a traditional wet binder, advantageously allows the curing oven 650 to use less energy to cure the dry binder within the pack. In the illustrated embodiment, the use of the dry binder in the curing oven 650 results in an energy savings in a range of from about 30.0% to about 80.0% compared to the energy used by conventional curing ovens to cure wet or aqueous binder. In still other embodiments, the energy savings can be in excess of 80.0%. The curing oven 650 can be any desired curing structure, mechanism or device or combinations thereof.
The third conveyor 648 conveys the cured pack to a fourth conveyor 652. The fourth conveyor 652 is configured to carry the cured pack to a cutting mechanism 654. Optionally, the cutting mechanism 654 can be configured for several cutting modes. In a first optional cutting mode, the cutting mechanism is configured to cut the cured pack in vertical directions along the machine direction D1 such as to form lanes. The formed lanes can have any desired widths. In a second optional cutting mode, the cutting mechanism is configured to bisect the cured pack in a horizontal direction such as to form continuous packs having thicknesses. The resulting bisected packs can have any desired thicknesses. Cutting the cured pack forms cut pack.
In the illustrated embodiment, the cutting mechanism 654 includes a system of saws and knives. Alternatively, the cutting mechanism 654 can be other structures, mechanisms or devices or combinations thereof. Referring again to
Optionally, prior to the conveyance of the cured pack to the cutting mechanism 654, the major surfaces of the cured pack can be faced with facing material or materials by facing mechanisms 662a, 662b as shown in
Referring to
Chopping mechanisms are known in the art and will not be described herein. The chopping mechanism 656 can be any desired structure, mechanism or device or combinations thereof.
Optionally, prior to the conveyance of the cut pack to the chopping mechanism 656, the minor surfaces of the cut pack can be faced with edging material or materials by edging mechanisms 666a, 666b as shown in
Referring again to
In the illustrated embodiment, the packaging mechanism 660 is configured to form the dimensioned pack into a package in the form of a roll. In other embodiments, the packaging mechanism 660 can form packages having other desired shapes, such as the non-limiting examples of slabs, batts and irregularly shaped or die cut pieces. The packaging mechanism 660 can be any desired structure, mechanism or device or combinations thereof.
Referring again to
As illustrated in
As further illustrated in
While the embodiment illustrated in
While exemplary embodiments of packs and methods for forming a pack from fibrous materials 610 have been described generally above, it should be appreciated that other embodiments and variations of the method 610 are available and will be generally described below.
Referring to
Referring again to
The thin high density tensile layer 1004 can take a wide variety of different forms. In one exemplary embodiment, the thin high density tensile layer 1004 is made from fiberglass fibers that are needled together. However, fibers of the high density tensile 1000 can be processed with other processes and/or products to accomplish the appropriate tensile strength. In one exemplary embodiment, the high density tensile layer 1004 is made from the high density pack 300 of the
In an exemplary embodiment, the high density tensile layer(s) 1004 is attached to the light density core 1002. The high density tensile layer(s) 1004 may be attached to the light density core 1002 in a wide variety of different ways. For example, the layers 1002, 1004 may be attached to one another with an adhesive, by an additional needling step, by heat bonding (when one or both of the layers 1002, 1004 include a binder), and the like. Any way of attaching the layers to one another can be employed. In an exemplary embodiment, the layers 1002, 1004 provide distinct properties to the insulation product 1000. In one exemplary embodiment, the insulation products 1000 illustrated by
In an exemplary embodiment, the thick, light density layer 1002 provides a high thermal resistance value R, but has a low tensile strength and the thin high density tensile layer 1004 provides a low thermal resistance value R, but a high tensile strength. The combination of the two layers provides an insulation product 1000 with both a high tensile strength and a high R value.
In an exemplary embodiment, the facing layer(s) 1004 is attached to the light density core 1002. The facing layer(s) 1004 may be attached to the light density core 1002 in a wide variety of different ways. For example, the layers 1002, 1004 may be attached to one another with an adhesive, by heat bonding, stitching and the like. Any way of attaching the layers to one another can be employed. In an exemplary embodiment, the layers 1002, 1004 provide distinct properties to the insulation product 1000. In an exemplary embodiment, the thick, light density layer 1002 provides a high thermal resistance value R, but has a low tensile strength and the facing layer 1004 provides tensile strength and other properties.
The examples illustrated by
The thin high density stratum 1054 can take a wide variety of different forms. In one exemplary embodiment, the high density stratum 1054 is made from fiberglass fibers that are needled together. However, fibers of the high density stratum 1054 can be processed with other processes and/or products to accomplish the appropriate tensile strength. In one exemplary embodiment, the high stratum 1054 is made in the same manner that the high density pack 300 of the
In an exemplary embodiment, the fibers of the high density stratum 1054 are attached to and/or entangled with the fibers of the light stratum 1052. Fibers of the high density stratum 1054 may be attached to fibers of the light density stratum 1052 in a wide variety of different ways. For example, the fibers of the strata 1002, 1004 may be attached to one another with adhesive, such as binder that is applied to the pack and/or by needling that is performed as the pack 1050 is made, and the like. Any way of attaching and/or entangling the fibers of the strata 1052, 1054 can be employed. In an exemplary embodiment, the strata 1052, 1054 provide distinct properties to the insulation product 1000. In one exemplary embodiment, the insulation products 1000 illustrated by
The insulation batts, packs and products of the embodiments of
In an exemplary embodiment, a thick, light density stratum 1052 provides a high thermal resistance value R, but has a low tensile strength and a thin high density tensile stratum 1004 provides a low thermal resistance value R, but a high tensile strength. The combination of the two strata provides a batt or pack 1050 with both a high tensile strength and a high R value. The strata can be configured to provide a variety of different properties to the batt or pack. For example, alternating thin, high density and thick, low density strata results in a batt or pack with excellent acoustic properties.
In one exemplary embodiment, the dry binder can include or be coated with additives to impart desired characteristics to the pack. One non-limiting example of an additive is a fire retardant material, such as for example baking soda. Another non-limiting example of an additive is a material that inhibits the transmission of ultraviolet light through the pack. Still another non-limiting example of an additive is a material that inhibits the transmission of infrared light through the pack.
Referring to
In certain embodiments, the duct 630 can include heat capturing devices, such as for example, heat extraction fixtures configured to capture the heat without significantly interfering with the momentum of the flow of the hot gasses and entrained glass fibers 622. In other embodiments, any desired structure, device or mechanism sufficient to capture the heat of fiberization can be used.
Referring to
The duct 678 can be connected to the duct 630 such as to allow mixing with the glass fibers 622 entrained in the flow of gasses. In this manner, the characteristics of the resulting pack can be engineered or tailored for desired properties, such as the nonlimiting examples acoustic, thermal enhancing or UV inhibiting characteristics.
In still other embodiments, it is contemplated that other materials can be positioned between the layers deposited by the cross-lapping mechanisms 634a and 634b on the first conveyor 636. The other materials can include sheet materials, such as for example, facings, vapor barriers or netting, or other non-sheet materials including the non-limiting examples of powders, particles or adhesives. The other materials can be positioned between the layers in any desired manner. In this manner, the characteristics of the resulting pack can be further engineered or tailored as desired.
While the embodiments shown in
While the embodiment illustrated in
As discussed above, optionally the trimmed materials can be returned to the flow of gasses and glass fibers in the ducts 630 and recycled in the forming apparatus 632a and 632b. In an exemplary embodiment, when an optional binder is included in the pack, the operating temperature of the forming apparatus 332a and 332b is kept below the softening temperature of the dry binder, thereby preventing the dry binder from curing prior to the downstream operation of the curing oven 550. In this embodiment, the maximum operating temperature of the curing oven 650 is in a range of from about 165° F. to about 180° F. In other embodiments, the maximum operating temperature of the curing oven 650 can be less than about 165° F. or more than about 180° F.
In one exemplary embodiment, the long, thin fibers 322 described herein are used in other applications than described above. For example,
In the
Referring to
The sizing may take a wide variety of different forms. For example, the sizing may comprise silicone and/or silane. However, any sizing may be employed depending on the application. The sizing may be adjusted based on the application the glass fibers are to be used in.
The small fiber diameter and the long fiber length allow the sized fibers to be used in applications where the fibers could not previously be used, due to excessive breakage of the fibers. In one exemplary embodiment, a fiber 322 having an approximately four micron diameter has a better flexural modulus and resulting strength than conventional fibers, because the finer fiber bends more easily without breaking. This improved flexural modulus and strength of the fiber help the fiber to survive processes that are typically destructive to conventional fibers, such as carding and air laid processes. In addition, the fine diameter of the glass fibers improves both thermal and acoustic performance.
The glass webs, packs, and staple fibers can be used in a wide variety of different applications. Examples of applications include, but are not limited to, heated appliances, such as ovens, ranges, and water heaters, heating, ventilation, and air conditioning (HVAC) components, such as HVAC ducts, acoustic insulating panels and materials, such as acoustic insulating panels for buildings and/or vehicles, and molded fiberglass components, such as compression molded or vacuum molded fiberglass components. In one exemplary embodiment, heated appliances, such as ovens, ranges, and water heaters, heating, HVAC components, such as HVAC ducts, acoustic insulating panels and materials, such as acoustic insulating panels for buildings and/or vehicles, and/or molded fiberglass components, such as compression molded or vacuum molded fiberglass components use or are made from a binderless fiberglass pack made in accordance with one or more of the embodiments disclosed by the present patent application. In an exemplary embodiment, since the fiberglass pack is binderless, there is no formaldehyde in the fiberglass pack. In one exemplary embodiment, heated appliances, such as ovens, ranges, and water heaters, heating, HVAC components, such as HVAC ducts, acoustic insulating panels and materials, such as acoustic insulating panels for buildings and/or vehicles, and/or molded fiberglass components, such as compression molded or vacuum molded fiberglass components use or are made from a dry binder fiberglass pack made in accordance with one or more of the embodiments disclosed by the present patent application. In this exemplary embodiment, the dry binder may be a formaldehyde free or no added formaldehyde dry binder. In a no added formaldehyde binder, the binder itself has no formaldehyde, but formaldehyde may be a byproduct if the binder is burned.
Fiberglass insulation packs described by this patent application can be used in a wide variety of different cooking ranges and in a variety of different configurations in any given cooking range. Published US Patent Application Pub. No. 2008/0246379 discloses an example of an insulation system used in a range. Published US Patent Application Pub. No. 2008/0246379 is incorporated herein by reference in its entirety. The fiberglass packs described herein can be used in any of the heating appliance insulation configurations described by Published US Patent Application Pub. No. 2008/0246379, including the configurations labeled prior art.
Referring to
As shown in
As further shown in
As shown in the example illustrated by
Fiberglass insulation packs described by this patent application can be used in a wide variety of different heating, ventilation, and air conditioning (HVAC) systems, such as ducts of an HVAC system. Further, the insulation packs described by this patent application can be provided in variety of different configurations in any given HVAC ducts. U.S. Pat. No. 3,092,529, Published Patent Cooperation Treaty (PCT) International Publication Number WO 2010/002958 and Pending U.S. patent application Ser. No. 13/764,920, filed on Feb. 12, 2013, all assigned to the assignee of the present application, discloses an examples of fiberglass insulation systems used in a HVAC ducts. U.S. Pat. No. 3,092,529, PCT International Publication Number WO 2010/002958 and Pending U.S. patent application Ser. No. 13/764,920 are incorporated herein by reference in their entirety. The fiberglass packs described herein can be used in any of the HVAC duct configurations described by U.S. Pat. No. 3,092,529, PCT International Publication Number WO 2010/002958 and Pending U.S. patent application Ser. No. 13/764,920.
In one exemplary embodiment, the insulation material that is used in the HVAC ducts disclosed by U.S. Pat. No. 3,092,529, PCT International Publication Number WO 2010/002958 and Pending U.S. patent application Ser. No. 13/764,920 is constructed from a dry binder fiberglass pack made in accordance with one or more of the embodiments disclosed by the present patent application. In this exemplary embodiment, the dry binder may be a formaldehyde free dry binder or a no added formaldehyde dry binder. In a no added formaldehyde binder, the binder itself has no formaldehyde, but formaldehyde may be a byproduct if the binder is burned.
In one exemplary embodiment, the insulation material that is used in the HVAC ducts disclosed by U.S. Pat. No. 3,092,529, PCT International Publication Number WO 2010/002958 and Pending U.S. patent application Ser. No. 13/764,920 is constructed from a binderless fiberglass pack made in accordance with one or more of the embodiments disclosed by the present patent application. In an exemplary embodiment, since the fiberglass pack is binderless, there is no formaldehyde in the insulation material.
Fiberglass insulation packs described by this patent application can be used in a wide variety of different acoustic applications and can have a variety of different configurations in each application. Examples of Acoustic insulation batts include Owens Corning Sound Attenuation Batt and Owens Corning Sonobatts insulation, which can be positioned behind a variety of panels of a building, such as ceiling tiles and wall. U.S. Pat. Nos. 7,329,456 and 7,294,218 describe examples of applications of acoustic insulation and are incorporated herein by reference in their entirety. The fiberglass packs described herein can be used in place of the insulation of the Owens Corning Sound Attenuation Batt and Owens Corning Sonobatts and can be used in any of the applications disclosed by U.S. Pat. Nos. 7,329,456 and 7,294,218. Additional acoustic applications for fiberglass insulation packs described by this patent application include, but are not limited to, duct liner, duct wrap, ceiling panels, wall panels, and the like.
In one exemplary embodiment, an acoustic insulation pack made in accordance with one or more of the embodiments of a binderless pack or dry binder pack disclosed by the present patent application tested according to ASTM C522 within 1,500 feet of sea level has an average airflow resistivity of 3,000-150,000 (mks Rayls/m). In one exemplary embodiment, an acoustic insulation pack made in accordance with one or more of the embodiments of a binderless pack or dry binder pack disclosed by the present patent application tested according to ASTM C423 within 1,500 feet of sea level has a Sound Absorption Average (SAA) in the range of 0.25 to 1.25. In one exemplary embodiment, an acoustic insulation pack made in accordance with one or more of the embodiments of a binderless pack or dry binder pack disclosed by the present patent application tested according to ISO 354 within 1,500 feet of sea level has a Sound Absorption coefficient aw in the range of 0.25 to 1.25.
In one exemplary embodiment, the insulation material that is used in place of the insulation of the Owens Corning Sound Attenuation Batt and Owens Corning Sonobatts and/or in any of the applications disclosed by U.S. Pat. Nos. 7,329,456 and 7,294,218 is constructed from a dry binder fiberglass pack made in accordance with one or more of the embodiments disclosed by the present patent application. In this exemplary embodiment, the dry binder may be a formaldehyde free dry binder or a no added formaldehyde dry binder. In a no added formaldehyde binder, the binder itself has no formaldehyde, but formaldehyde may be a byproduct if the binder is burned.
In one exemplary embodiment, the insulation material that is used in place of the insulation of the Owens Corning Sound Attenuation Batt and Owens Corning Sonobatts and/or in any of the applications disclosed by U.S. Pat. Nos. 7,329,456 and 7,294,218 is constructed from a binderless fiberglass pack made in accordance with one or more of the embodiments disclosed by the present patent application. In an exemplary embodiment, since the fiberglass pack is binderless, there is no formaldehyde in the insulation material.
Fiberglass insulation packs described by this patent application can be used in a wide variety of molded fiberglass products. For example, referring to
Referring to
Referring to
In the example illustrated by
Referring to
Referring to
Referring to
In the example illustrated by
In one exemplary embodiment, the insulation material that is molded in accordance with the embodiment illustrated by
In one exemplary embodiment, the insulation material that is molded in accordance with the embodiment illustrated by
Referring to
The packs 2700 can be made from any of the insulation materials disclosed by the present application. The packs 2700 can be made from one or multiple layers of the insulation materials described by the present application. The packs may include binder or be binderless. In one exemplary embodiment, the packs 2700 are binderless, and the insulation pads 2704 are used to insulating pipes and vessels that reach temperatures that are greater than 500 degrees F., greater than 700 degrees F., or even greater than 800 degrees F., such as 1000 degrees F.
In one exemplary embodiment, these insulation pads have a density of 4.5 to 5.5 lb/ft3, such as about 5 lb/ft3. In one exemplary embodiment, one of the insulation materials disclosed by the present application is needled to have density of 4.5 to 5.5 lb/ft3, such as about 5 lb/ft3 to make the packs 2700.
Table 3 provides ranges of thermal conductivity K and thermal resistance R values for one-inch and two inch packs at various temperatures. These thermal conductivity K and thermal resistance R values are provided using the mean temperature difference method defined by ASTM-C-177. ASTM-C-177 is incorporated herein by reference.
4-2.5
The insulation pads 2704 may be between 0.5 inches thick and 5 inches thick. For example, the insulation pads 2704 may be provided in one and two inch thicknesses. In one exemplary embodiment, a one-inch thick pad includes a single one-inch thick pack 2700. In one exemplary embodiment, a two-inch thick pad includes a two stacked one-inch thick packs 2700. In one exemplary embodiment, binderless packs 2700 made as described in the present application are hydrophobic. In one exemplary embodiment, the surface of the pack is water repellant. The hydrophobic nature of the packs 2700 and/or the water repellant nature of the surface of the pack 2700 makes the pads 2704 suitable for outdoor use and other applications where the pad 2704 will be subjected to moisture.
The envelopes 2702 can be made from a wide variety of different materials. Any material that allows the pad 2704 to be placed against a pipe or vessel that has a surface temperature that is 500 degrees F. or higher can be used. In one exemplary embodiment, the envelope 2702 can be closed by stitching. In one embodiment, fabric stitches 27650 pass through the envelope 2702 and the pack 2700. In one exemplary embodiment, conventional upholstery stitches can be used to stitch the pack(s) and/or the envelope using conventional upholstery stitching tools. Examples of suitable materials for the envelopes 2702 include, but are not limited to, silicone impregnated fiberglass fabrics, silica fabrics, stainless knitted mesh, metalized fiberglass fabrics, such as aluminized fiberglass fabrics.
Several exemplary embodiments of mineral fiber webs, packs, and staple fibers and methods of producing mineral fiber webs, packs, and staple fibers are disclosed by this application. Mineral fiber webs and packs and methods of producing mineral fiber webs and packs in accordance with the present invention may include any combination or subcombination of the features disclosed by the present application.
In accordance with the provisions of the patent statutes, the principles and modes of the improved methods of forming a pack from fibrous materials have been explained and illustrated in its preferred embodiment. However, it must be understood that the improved method of forming a pack from fibrous materials may be practiced otherwise than as specifically explained and illustrated without departing from its spirit or scope.
This application is a continuation of U.S. application Ser. No. 14/715,849, filed on May 19, 2015, which is a continuation in part of U.S. application Ser. No. 14/465,908 filed on Aug. 22, 2014, which is a continuation in part of U.S. application Ser. No. 13/839,350 filed on Mar. 15, 2013, which is a continuation in part of U.S. application Ser. No. 13/632,895 filed on Oct. 1, 2012, now abandoned, which claims priority from U.S. Application No. 61/541,162, filed on Sep. 30, 2011, all of which are incorporated herein by reference in their entirety. This application is a continuation of U.S. application Ser. No. 14/715,849, filed on May 19, 2015, also claims the benefit of U.S. Application No. 62/011,890, filed on Jun. 13, 2014, which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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61541162 | Sep 2011 | US | |
62011890 | Jun 2014 | US |
Number | Date | Country | |
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Parent | 14715849 | May 2015 | US |
Child | 18658377 | US |
Number | Date | Country | |
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Parent | 14465908 | Aug 2014 | US |
Child | 14715849 | US | |
Parent | 13839350 | Mar 2013 | US |
Child | 14465908 | US | |
Parent | 13632895 | Oct 2012 | US |
Child | 13839350 | US |